The present disclosure relates to a bill of material (BM) automatic calculation method for plant stationary equipment, and more particularly, to a BM automatic calculation method for plant stationary equipment capable of automatically calculating BM data for purchasing a plate required quantity required for manufacturing stationary equipment through cutting plan and optimization deployment in order to manufacture stationary equipment using data extracted from a strength calculation program of the plant stationary equipment prepared in a plant engineering step. The present disclosure has an advantage of greatly reducing the labor force by automatically calculating the cutting plan drawing, the nesting plan drawing, and required BM of the plate of the stationary machine which has been manually performed in the related art.

An apparatus is provided. The apparatus including a plurality of network interfaces, including a first network interface and a second network interface. The apparatus also includes a processor with two or more independent processing units, including a first independent processing unit and a second independent processing unit. The apparatus further includes a memory having first instructions and second instructions stored thereon. Execution of the first instructions, cause the first independent processing unit to execute operations associated with a first operating system and communicate, via the first network interface, over a bi-direction communication, with one or more platform computing devices. Execution of the second instructions, cause the second independent processing unit to execute real-time operations associated with a second operating system and communicate, via the second network interface, with one or more computing devices each having one or more sensors thereon.

The embodiments of the present disclosure provide a polishing head management system and method. The polishing head management system includes: a storage device, a pick-and-place device and a data acquisition device, where the storage device is used to store polishing heads; the pick-and-place device is used to pick a polishing head or place a polishing head into the storage device; the data acquisition device is connected with the storage device and the pick-and-place device, and is used to record at least one management cycle of the polishing head.

The disclosure relates to a method, an electronic device and a computer program product for reducing a carbon dioxide footprint associated with a production process. The carbon dioxide footprint has at least an amount of carbon dioxide emitted during the production process. The method includes the step of obtaining a parameter indicative of a selected cutting feature for production by a cutting tool, the step of obtaining a parameter indicative of a selected work-piece material for production by a cutting tool, the step of determining a set of cutting tools for production based on the obtained parameters, and the step of determining a cutting tool for production from the determined set of cutting tools based on carbon dioxide emission information data associated with each cutting tool in the determined set of cutting tools.

A modular modeling engine is provided for industrial automation applications. The module may be instantiated upon demand, such as upon receipt of annotated data for a system or process being monitored and/or controlled. The model is agnostic insomuch as little or no prior knowledge is required of the system or process. Variables, functions, and their combinations are selected and the model is refined automatically. A data structure is received for instantiation of the model, and following modeling, a similar data structure is produced. The module may be used together with other modules for caning out complex automation processing at the same or multiple levels in an automation setting.

A method is provided for automatically or semi-automatically analyzing process hazards and validating protection mechanisms for an industrial process. The method can involve establishing communication between a simulation tool and a process hazard analysis tool. The simulation tool simulates operation of the process according to a process model. The method can further involve creating, using the process hazard analysis tool, conditions for hazards in the process based on information learned about the industrial process from the simulation tool; for each of the hazards, simulating the hazards using the simulation tool and attempting to prevent the hazards using the process hazard analysis tool by introducing protective mechanism(s) to the process; and evaluating effectiveness of the introduced protective mechanisms for each of the hazards and creating safety requirements for the process based on the evaluated effectiveness. The safety requirements are used to generate a safety application program, such as for a PLC.

A system and method for packaging pine straw and a packaged mass of pine straw made therefrom, the method including providing an electronically-controlled system configured for packaging pine straw, the system including system logic that controls conveying, fluffing, cleaning, compressing and packaging of the pine straw, and using the system to compress a mass of pine straw into a rectangular mass of pine straw and enclosing the rectangular mass of pine straw within a flexible plastic sheet thereby forming a substantially rectangular packaged mass of compressed pine straw.

A method for engineering a method-or process-engineering plant with at least one function module, a corresponding function module and a stored program control, wherein the function module includes the stored program control and the method-or process-engineering module that can be controlled or regulated thereby fur use as part of the plant, where a parameter-configurable user program is loaded into the stored program control, and information for the integration of the function module in a file is provided, during engineering of the plant, which defines the parameters for the application-specific configuration of the function module via a plant-engineering tool and stored via an interface specified in a formal description language, for configuration of the user program, in a memory area of the control such that an engineering tool, which is specific to the respective stored program controls used within function modules, is advantageously no longer required.

A method and a tool controller enable different functionality sets for at least a first and a second tool. The method includes retrieving at least a first license type that specifies a first set of functions allowed to be performed by at least the first tool retrieving at least a second license type that specifies a second set of functions allowed to be performed by at least the second tool. The method further includes enabling the first set of functions for at least the first tool and enabling the second set of functions for at least the second tool.

A method of planning works for robots includes creating a work plan for a plurality of robots, each having a work tool, sharing at at least one station a work to a plurality of work parts of the workpiece. The method includes the steps of calculating a distribution of the work parts to the robots, calculating, as a robot operation, a work order of the work parts and a moving path of the work tool for each of the robots based on the calculated work distribution, and calculating a disposed location of each of the robots with respect to the workpiece and a station where the robot is disposed so that an inter-robot interference does not occur during execution of the calculated robot operation.