A method includes defining a manufacturing transformation for a mobile workpiece based on mobile workpiece state information of the mobile workpiece, where the manufacturing transformation is an automated operation to be performed on the mobile workpiece. The method includes selecting a set of one or more manufacturing systems from among the one or more manufacturing systems for the mobile workpiece based on the manufacturing transformation and manufacturing system state information associated with the one or more manufacturing systems, where the manufacturing system state information provides data related to at least one of availability, capability, and constraints of the of the one or more manufacturing systems. The method includes defining manufacturing process steps of the manufacturing transformation based on the set of one or more manufacturing systems. The method includes defining a location for performing the manufacturing process steps on the mobile workpiece.

An edge device interface system and method for monitoring, recording, and calculating control and response signals generated by and between an injection molding system including an injection-molding machine and a robotic handling device. The edge device interface system of the invention includes an edge device interposed between the connector of the injection-molding machine and the connector of a robotic handling device using standardized connectors. The edge device interface system may be interposed between the connector of the injection-molding machine and the connector of a robotic handling device to emulate the function of either device as desired. The edge device interface system and method utilizes data observed both from standardized connectors and auxiliary inputs to provide insight into molding process steps and equipment, including what components of the injection molding system that may be contributing to any molding process instability or inefficiency, and for generating signals for real-time adjustment of the molding process.

A machining system includes an information processing system, a first machine tool communicable with the information processing system, and a second machine tool communicable with the information processing system. The information processing system includes a reception unit that receives setting data set in the first machine tool, a storage device that stores the setting data received from the first machine tool, and a transmission unit that transmits the setting data of the first machine tool stored in the storage device to the second machine tool in response to a setting data acquisition request, when the setting data is inheritable to the second machine tool. The second machine tool includes a setting unit that allows the second machine tool to inherit the setting data received from the information processing system.

A robot programming system according to an aspect of the present disclosure includes: a robot program storage section; a press program storage section; a template program setting section that causes the robot program storage section to store, as an initial version of a robot program, a template program that instructs a robot how to move basically; a model placing section that places three-dimensional models of a workpiece, the robot, and a press machine in a virtual space; a robot movement processing section that causes the three-dimensional model of the robot to move; a press movement processing section that causes the three-dimensional model of the press machine to move; an interference detection section that detects interference between the three-dimensional models; and a robot program modification section that modifies a robot program stored in the robot program storage section to prevent interference detected by the interference detection section.

A control system (10) includes: a manual operating device (1) that generates an operation signal in accordance with rotation of a dial (11) by an operator; a machine tool controller (4) and a robot controller (5) that are connected in such a manner as to be communicable with each other and that control a machine tool (6) and a robot (7), respectively, based on the operation signal; and an operational-target setting unit (2, 3) that sets an operational target for the manual operating device (1) selectively between the machine tool (6) and the robot (7). The manual operating device (1) is connected to one of the controllers (4, 5) and inputs the operation signal to the one of the controllers. When the operational-target setting unit (2, 3) sets the operational target as a control target (6) or (7) to be controlled by the other of the controllers (4, 5), the one of the controllers (4, 5) transmits the operation signal or a signal based on the operation signal to the other of the controllers.

A control device that controls polygon turning to simultaneously rotate a workpiece and a tool and form a polygon on a surface of the workpiece inputs information on misalignment in a rotation direction of a cutting tool T attached to a tool body, generates adjustment pulses to correct the misalignment in the rotation direction of the cutting tool T, and generates a rotation command for rotating, at a predetermined angular velocity, a tool axis used for performing polygon turning. The control device then superimposes the generated adjustment pulses on the generated rotation command in idle running of the tool, corrects the misalignment in the rotation direction of the cutting tool T, and thereby improves the precision of the polygon turning.

A control system for evaluating residual operating life of a machine component of a machine tool includes a sensor and a control system. The sensor is disposed on the machine tool and is configured to sense movement of the machine component. The control device is configured to calculate a length of time based on a sense signal received from the sensor and sampled at a time point right after the machine component is freshly oiled, and to enable output of an alarm when determining that the length of time thus calculated is smaller than a predetermined length.

A method for assisting with the positioning of a drill bit for boring a component, which includes capturing images of a first component which has notable points, of calculating a digital representation from these images, of superposing the digital representation thus calculated and a digital design representation of the component, of evaluating the distances of the centers of bores to be created with respect to the notable points, and of positioning a drill bit with the aid of a camera and of the evaluated distances. The method continues in the same way for the other components to be assembled.

A system, apparatus and method for determining operational configuration of asset are provided. The method includes receiving a set of operating parameters associated with the asset, identifying data associated with the asset based on the received set of operating parameters, configuring a second digital twin of the asset based on the data identified from first knowledge database, simulating a behavior of the asset based on the configured second digital twin in a simulation environment, and determining an operational configuration associated with the variant of the asset based on results of the simulation.

Production system for processing workpieces, having a robot module, a workpiece carrier module and a machining module, all of them being working modules, wherein each of said working modules includes an interface surface, the interface surface having a supply interface and a communication interface, wherein the robot module includes a robot and a robot controller for handling workpieces, wherein the workpiece carrier module includes a plurality of workpiece locations for receiving unmachined and finished workpieces, wherein the machining module includes a processing system for carrying out at least one processing operation on at least one workpiece; wherein a data carrier is assigned to each of the working modules, which a data carrier stores processing data, the processing data including a transfer position for workpieces and being coded for processing in the robot controller of the robot module.