The machine tool apparatus comprises: multiple work machine modules configured to sequentially perform a series of manufacturing-related operations on a workpiece; a robot configured to convey the workpiece between the multiple work machine modules; an individual information-providing device configured to provide an individual information to the workpiece conveyed into the multiple work machine modules and subjected to manufacturing-related operations; a storage device; and a control device configured to link the manufacturing history of manufacturing-related operations performed on the workpiece by the multiple work machine modules and store the information in the storage section, the workpiece being a workpiece to which the individual information was provided by the individual information-providing device.

A manufacturing history management system according to an aspect of the present disclosure includes a data generation unit, a data storage unit, and a data extraction unit. The data generation unit generates manufacturing history data by associating internal void information specific to a product and manufacturing history information of the product with a product identification code. The data storage unit stores the manufacturing history data relating to a plurality of the products generated by the data generation unit. The data extraction unit checks the internal void information of the manufacturing history data of the plurality of products stored in the data storage unit against the internal void information of a predetermined product and extracts the manufacturing history data that matches the internal void information of the predetermined product from the manufacturing history data of the plurality of products stored in the data storage unit.

A system for utilizing an identification marker on a tool part for determining a dimension thereof. The system includes a reader device for reading a machine readable code, and an electronic device connected to the reader device. The electronic device has a processing circuitry that causes the system to detect with the reader device, an identification marker at a tool part, wherein the identification marker is a unique machine readable code read by the reader device, and the unique machine readable code of the identification marker, and obtain from the unique machine readable code, individual dimension information data including at least one individually measured dimension of the tool part measured when manufacturing the tool part. A method and a computer program product for utilizing an identification marker on a tool part to be used for determining a dimension of the tool part and to a tool part is also provided.

The present disclosure discloses an Industrial Internet of Things, a control method, and a medium for regulating multi-type of working parameters. The Industrial Internet of Things may include a user platform, a service platform, a management platform, a sensor network platform and an object platform that interact in turn. The service platform, the management platform and the sensor network platform may be all arranged in a front sub-platform layout. The control method may be applied to the Industrial Internet of Things. The optimal value of the working parameter may be obtained based on the product manufacturing data, and the optimal selection of the parameter may be realized under the condition of ensuring the production, and then the working parameters of all the manufacturing devices may be further regulated or determined.

The present teachings relate to a method for digitally tracking a chemical product manufactured at an industrial plant comprising at least one equipment; and, the product being manufactured by processing, via the equipment, at least one input material using a production process, which method comprises: providing, via an interface, an object identifier comprising input material data; wherein the input material data is indicative of one or more property of the input material, receiving, via the interface, process data from the equipment; the process data being indicative of the process parameters and/or equipment operating conditions that the input material is processed under, appending, to the object identifier, at least a part of the process data. The present teachings also relate to a system for digitally tracking a chemical product and a software product.

A method of extracting data embedded in a 3D object includes a 3D scanning device scanning a 3D object and extracting data embedded as physical representations in the 3D object. A processing device will identify, from the extracted data, instructions for causing the processing device to perform an action such as identifying building instructions for printing a copy of the 3D object. The processing device will also perform the action to identify the building instructions, and cause a 3D printer to use the building instructions to print the copy of the 3D object. The processing device may be part of the 3D scanning device or part of another device or system that is in communication with the 3D scanning device.

A manufacturing history management system according to an aspect of the present disclosure includes a data generation unit, a data storage unit, and a data extraction unit. The data generation unit generates manufacturing history data by associating internal void information specific to a product and manufacturing history information of the product with a product identification code. The data storage unit stores the manufacturing history data relating to a plurality of the products generated by the data generation unit. The data extraction unit checks the internal void information of the manufacturing history data of the plurality of products stored in the data storage unit against the internal void information of a predetermined product and extracts the manufacturing history data that matches the internal void information of the predetermined product from the manufacturing history data of the plurality of products stored in the data storage unit.

A method for compensating for the deflection of a milling cutter during the machining of a workpiece by a numerically controlled machine tool having a plurality of axes includes: executing a learning cut on a test workpiece having a known geometry by the milling cutter mounted on a tool spindle in a climb milling mode, and in doing so, ascertaining a correlation between a quantity that is proportional to the torque of the drive of the tool spindle and the deflection of the milling cutter normal to a surface of the test workpiece, the deflection being determined by comparing the actual contour of the test workpiece to a setpoint contour. This is followed by storing of the correlation for the milling cutter and machining of the workpiece by the milling cutter in a climb milling mode, while utilizing the stored correlation for compensating for the deflection of the milling cutter by applying a positional correction that is proportional to the quantity to a setpoint position of the axes of the machine tool.

The machine tool apparatus comprises: multiple work machine modules configured to sequentially perform a series of manufacturing-related operations on a workpiece; a robot configured to convey the workpiece between the multiple work machine modules; an individual information-providing device configured to provide an individual information to the workpiece conveyed into the multiple work machine modules and subjected to manufacturing-related operations; a storage device; and a control device configured to link the manufacturing history of manufacturing-related operations performed on the workpiece by the multiple work machine modules and store the information in the storage section, the workpiece being a workpiece to which the individual information was provided by the individual information-providing device.

A method of extracting data embedded in a 3D object includes a 3D scanning device scanning a 3D object and extracting data embedded as physical representations in the 3D object. A processing device will identify, from the extracted data, instructions for causing the processing device to perform an action such as identifying building instructions for printing a copy of the 3D object. The processing device will also perform the action to identify the building instructions, and cause a 3D printer to use the building instructions to print the copy of the 3D object. The processing device may be part of the 3D scanning device or part of another device or system that is in communication with the 3D scanning device.