A tool identification system for fitting to a tool includes a data memory configured to store data specific to the tool, and a standardized data interface configured to provide the data for a superordinate device having a corresponding data interface. The data memory is included in a microprocessor system configured to keep the standardized data interface ready, with the result that the data in the data memory can be read or written by a device using the microprocessor system and using the standardized data interface.

A method for confirming cutting tool's location includes: a position calculation unit basing on plural sleeve positions in a tool magazine to train and obtain training posture data and training signal strength data of each the sleeve position; and the position calculation unit sending a tool call command to move a target cutting tool among the cutting tool to a tool exchange position. The latter step includes: obtaining a posture data and a signal strength data of the target cutting tool; based on the posture data and the signal strength data, the position calculation unit comparing the training posture data and the training signal strength data to confirm a target sleeve location of the target cutting tool; and, rotating the tool magazine to move the target cutting tool from the target sleeve location to the tool exchange position. In addition, a machine system using the method is also provided.

Method and an arrangement for monitoring status of a production device configured to implement an industrial process or industrial production with a control device with sensors and actuators, where at least one further sensor is carried through the production device with a product being processed by the production device, where further signals are wirelessly transmitted to a status-monitoring device by the further sensor, and where the signals and/or status information items and the further signals are placeable in relationship with one another to generate status information item about the production device such that it is possible to plan the status monitoring separately from the production device, and possible to combine information items of the industrial control device with the information items and data of a mobile sensor (further sensor) that passes through the production device, such that more precise status information items about the production device status can be acquired.

An intelligent workpiece system includes a workpiece comprising a portion of a product; and an embedded computing system attached to the workpiece. The embedded computing system is configured to communicate with machines in a manufacturing environment to facilitate assembly of the workpiece into the product at a plurality of assembling areas.

Robots capable of accommodating dynamic replacement of end effectors load and run software that allows the end effector to be operated without change to the main control program. The driver may be dynamically linked and run during program execution when the corresponding end effector is detected. Typically, the robot controller will store a library of drivers, and load the appropriate driver when a new end effector is detected.

In various embodiments, a tool plate configured to receive a robotic end effector is removably matable with a robot appendage via a quick-release mechanism.

Signals are transmitted between a device placed on an object and at least one further device. Based on measurement of the signals transmitted between the device and the at least one further device, a position of the object is determined. Further, data associated with the object are stored in the device. The stored data are then transmitted from the device.

A device (10) is placed on an object (30) handled by a robot (100). Based on measurements performed by at least one sensor of the device (10), engagement of the robot (100) with the object (30) is detected. The measurements may for example include acceleration measurements which allow for detecting movement of the object (30) caused by the robot (100).

Systems and methods for controlling chlorinators for pools and spas are provided. A controller communicates with a processor positioned within a replaceable cell cartridge of a chlorinator, to allow for remote control and diagnosis of the chlorinator and/or cell cartridge. The cell cartridge stores, in non-volatile memory on board the cartridge, one or more parameters associated with the cartridge. The controller can obtain this information from the processor of the cell cartridge, and can use same to configure operation of the chlorinator. Information relating to remaining cell life can be updated by the controller and stored in the non-volatile memory of the cell cartridge. Electrical and software-based mechanisms are provided for ensuring operation of only compatible cell cartridges with the chlorinator. A system for remotely diagnosing errors associated with the chlorinator is also provided.

A system for monitoring maintenance for manufacturing apparatuses in a facility is provided. The system includes at least one manufacturing apparatus, the manufacturing apparatus including an RF identification tag and a module, and a control system. The control system is configured to receive, from the module, operational status information that indicates time periods during which the manufacturing apparatus is in operation, determine a cumulative time duration of operation for the manufacturing apparatus, retrieve a predetermined maintenance interval for the manufacturing apparatus, determine whether the cumulative time duration of operation exceeds the predetermined maintenance interval, and in response to a determination that the cumulative time duration of operation exceeds the predetermined maintenance interval, i) output a signal that causes the manufacturing apparatus to discontinue operation, and ii) cause instructions for completing a required maintenance procedure to be displayed on a display device in communication with the control system.