The present disclosure provides a CIM system, a control method and a production informatization system. The CIM system comprises an integrated control device and an integrated communication device. The integrated control device comprises an interface module and an integrated control module; wherein the interface module is arranged to receive a control command and identify a controlled device at which the control command is directed; the integrated control module is arranged to obtain, based on the control command, a control instruction that is recognizable by the controlled device and transmit the control instruction to the integrated communication device. The integrated communication device is arranged to determine a communication protocol type between it and the controlled device, and encapsulate the control instruction into a control message of corresponding communication protocol type to transmit to the controlled device. The computer integrated manufacturing system provided by the present disclosure can improve the control efficiency for the controlled device.

A processing apparatus includes a central control unit, and a processing quality prediction unit, a processing unit, and a tool compensation unit which are respectively connected with the central control unit electrically. The processing quality prediction unit implements a virtual processing quality prediction method to predict the processing quality of the workpiece, output an accurate data of quality to the central control unit, and generate tool path for the processing unit to process the workpiece. The central control unit judges the data from the processing quality prediction unit and outputs the data to the tool compensation unit to calculate tool compensation data. The tool compensation unit provides the tool compensation data to the processing quality prediction unit to form a new processing path. Then the processing unit implements the compensated processing path to process the workpiece.

A system and method for data collection and frequency analysis with self-organization functionality includes analyzing with a processor a plurality of sensor inputs, sampling with the processor data received from at least one of the plurality of sensor inputs at a first frequency, and self-organizing with the processor a selection operation of the plurality of sensor inputs.

A system and method includes integrating a plurality of installation modules each having at least one process-technical unit which, besides hardware, also houses control technology, to form a modularly constructed overall installation. The installation modules are arranged three-dimensionally and, according to the description of the overall installation, are connected mechanically and electrically to one another. Between the installation modules, at least one coupling for data exchange is formed via one or more communication protocols. A configuration of the overall installation is assembled and stored on a central server unit having a data link to the installation modules. Each installation module is allocated at least one access path to the configuration. After the installation modules have been started, each installation module forms a connection to the configuration via the access path, reads configuration data respectively intended for the installation module to be read via the access path and, in accordance with the configuration data read, forms the communication links to at least one further installation module, wherein links are formed between individual data objects and also service interfaces are requested, and the installation modules provide the relevant function thereof to the outside via data points and services.

A field device for determining a process variable is provided, the field device including: a sensor circuitry configured to sense a measured value of the process variable; a communication circuitry configured to transmit the measured value wirelessly to a receiver; a position determination circuitry configured to determine a geographic position of the field device; and a control circuitry configured to determine, as a function of a current geographical position of the field device, at least one of: (a) a current measurement rate at which the sensor circuitry acquires measured values of the process variable, and (b) a current data transmission rate at which the communication circuitry transmits measured values to the receiver. A method of operating a field device is also provided.

A support device is connected to a controller system that controls a control target. The controller system can execute an incident response operation of changing a behavior in accordance with an incident that may occur in the controller system. The support device includes a selection module and a setting module. The selection module receives selection of a facility type corresponding to the control target among plural facility types which is preset. The setting module reflects a response rule corresponding to the selected facility type in the controller system by referring to a response rule that is prepared in advance for each of the facility types and defines a behavior for an incident.

A controller is provided for building equipment including a plurality of devices that operate in parallel to affect an environmental condition of a building. The controller includes one or more processing circuits including one or more processors and memory. The memory store instructions that, when executed by the one or more processors, cause the one or more processors to perform operations. The operations include lowering an upper bound or raising a lower bound of one or more constraints based on a minimum off schedule or a minimum on schedule for the building equipment, performing an optimization of an objective function subject to the one or more constraints to generate control decisions for the building equipment, and operating the building equipment in accordance with the control decisions to affect the environmental condition of the building.

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 method for employing a plurality of automated machines to deposit composite material includes a first tool located in a first station and a second tool located in a second station. The first station and the second station are located on a production line. The first station includes at least one automated machine of the plurality of automated machines and the second station includes at least two automated machines of the plurality of automated machines. At least one of the automated machines is movable from the second station to the first station. The method includes monitoring machine capacity and workload requirements of the plurality of automated machines. The method further includes determining an efficiency threshold based upon the machine capacity and workload requirements. The method further includes reallocating at least one of the automated machines from the second station to the first station once the efficiency threshold is met.

A system and method for data collection and frequency analysis with self-organization functionality includes analyzing with a processor a plurality of sensor inputs, sampling with the processor data received from at least one of the plurality of sensor inputs at a first frequency, and self-organizing with the processor a selection operation of the plurality of sensor inputs.