A parameter setting device sets parameters for driving a machine in which a numerical controller is incorporated. The parameter setting device uses a machine configuration file in which information is described pertaining to the configuration of the machine. Furthermore, the parameter setting device is equipped with a parameter generating unit for generating parameters based on the machine configuration file, and a parameter setting unit for setting the generated parameters in the numerical controller.

A method for an automated configuration of an industrial controller unit comprises sending, from a server system, an instruction message and a verification token to a client device via a first communication network. The instruction message comprises information pertaining to a modification of an industrial controller unit, and the verification token pertains to a completed modification of the industrial controller unit. The method further comprises receiving, at the server system, a verification message pertaining to the verification token, and providing, from the server system, an industrial program and/or a parameter for an industrial program to the industrial controller unit via a second communication network, in response to receiving the verification message.

A controller including: a positional deviation calculating unit that calculates positional deviation using a position command directed to a servo motor for driving a cutting tool, etc., and a position feedback value corresponding to the position of the cutting tool, etc.; an oscillation command calculating unit that calculates an oscillation command using the position command and a spindle axis angle of the rotated work, etc., or using the position feedback value and the spindle axis angle; an oscillation offset calculating unit that calculates an offset for the oscillation command using the positional deviation, the oscillation command, and the spindle axis angle; and a driving unit that determines a drive signal for the servo motor based on the positional deviation, the oscillation command, and the oscillation offset, and outputs the drive signal.

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 machine system includes two machines, a computer communicably connected to the machines, and a base software application and an operation software application installed in the computer. The base software application includes a first communication module that is a program portion to execute transmission and reception of first machine information to be outputted from each machine and second command information to be outputted to each machine, and a second communication module that is a program portion to execute transmission and reception of first command information to be inputted from the operation software application to the base software application and second machine information to be outputted from the base software application to the operation software application.

It is possible to make data for manufacturing devices available in a standard format using an adapter that would automatically interrogate the device and use the information gained from the machine to generate a data translation file. The data translation file could subsequently be used by an agent to interpret a data stream provided by the adapter for the manufacturing device.

In a component mounting system having an inspection device performing a mounting inspection after component mounting, a correction value for correcting a mounting program is calculated based on board inspection information including fed-back component position deviation information, a component is mounted on a board in accordance with the mounting program corrected based on the calculated correction value, and a “present value” based on most recent board inspection information and a “pre-correction evaluation value” are displayed together on an evaluation value display screen as evaluation values representing accuracy at a time of the mounting based on the board inspection information during this component mounting work, the “pre-correction evaluation value” being calculated based on a temporary position deviation amount pertaining to a case where it is assumed that no correction based on the calculated correction value has been performed.

A method and apparatus for machining a part for an assembly. First sensor data is acquired for a surface of a first part from a first sensor system. Second sensor data is acquired for a set of existing holes in a second part from a second sensor system. A surface model of the surface of the first part is generated using the first sensor data. First offset data is computed based on a nominal model of a third part that is nominally positioned relative to the surface model within a three-dimensional virtual environment. Second offset data is computed for the set of existing holes using the second sensor data. Overall offset data is generated using the first and second offset data, wherein the overall offset data is used to drill a set of holes in the third part for use in fastening the third part to the second part.

A method and apparatus for customizing tool paths. A reference tool path is identified for a tool based on an expected shape for a surface of an object. Offset data is generated for a plurality of sample points identified for use in evaluating the surface of the object. The offset data identifies a difference between the expected shape for the surface of the object and an actual shape of the surface of the object. The reference tool path is modified using the offset data to form a modified tool path for the tool.

A method of processing structurally identical workpieces using a numerically controlled workpiece processing apparatus includes processing a first workpiece according to a first desired tool path specified for a tool of the numerically controlled workpiece processing apparatus by closed-loop controlling a working distance between the tool and the workpiece to achieve a defined desired distance, such that when processing the first workpiece, the tool is moved along a distance-controlled actual tool path. The method further includes optimizing the first desired tool path for a second workpiece based on the distance-controlled actual tool path of the first workpiece to provide a second desired tool path and processing the second workpiece according to the second desired tool path.