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.

Method for producing logs (B1, B2) of continuous thin products, or web products, in optimized manner by tracking defects in the surface and/or in the thickness detected on the products, comprising a step of continuously winding a thin product (T) into logs (B1, B2) on a winding machine, in order to produce at least one primary log, a step of identifying any defects in the surface and/or the thickness of said continuous thin product, a step of storing in a database system (31), outside the primary log, information related to said defects comprising at least the position of said defects with respect to a reference system associated with the primary log, a step of assigning a primary ID code to said primary log, a step of marking said primary log with said primary code, a step of associating, in said database system (31), information on said defects with the primary ID code of the primary log, so that, in said database, to a given primary ID code information are associated related to defects in the surface and/or the thickness of the respective primary log, that can be identified based on their position on the primary log, a step of using said information on the defects of the primary log, stored in the database system (31), in order to optimize at least one subsequent processing of the product wound into the respective primary log, said use providing for recognizing the primary code of the primary log being processed and the processing of the product based on the information on the surface defects associated to the primary log.

A tooling system that includes a drive unit configured to provide rotational force to a tool member. The tool member is attached at a mount on the drive unit. A camera associated with the drive unit is aligned to capture a target on the tool member. The data is sent to a controller that identifies the tool member based on the target. The controller determines whether the tool member is correct for performing an operation on a work piece. If the tool member is correct, the controller may set one or more operating parameters on the drive unit. If the controller determines that the tool member is not correct, the drive unit is disabled. Further, a signal may be sent to inform an operator of the issue.

Systems and methods for fuel cell stack part serialization and tracking. In an embodiment, a barcode may be applied to a fuel cell stack part which may identify the fuel cell stack part. In an embodiment, the barcode may be applied as ink on a green fuel cell stack part prior to sintering. In an embodiment, a portion of a fuel cell stack part may be imaged and pattern recognition techniques may be utilized to identify the fuel cell stack part based on the unique features of fuel cell stack part. In an embodiment, portion of a fuel cell stack part may be measured to generate one or more series of unique volume/area values and one or more series of unique volume/area values may be utilized to identify the fuel cell stack part.

A method for processing tool data on a machine tool having a data interface for connection to a tool management system and an associated control device and computer program product. The method comprises the steps of: acquiring a unique tool identifier, WID, of a tool to be picked up; matching the acquired WID with previously known tool identification data of the machine tool; if it is determined that the tool to be picked up is not yet known and/or updated tool data for the WID are available: automatically, via the data interface, retrieving tool data directly from the tool management system based on the acquired WID or automatically retrieving the tool data directly from the tool to be picked up; determining a loading location for the tool to be picked up based on the retrieved tool data and preferably, picking up the tool at the determined loading location.

A robotic system comprising an end effector-mounted sensor is disclosed. In various embodiments, a robotic arm is manipulated to move a sensor to a position such that an object of interest is within a read range of the sensor. A sensor data read by the sensor is received via a communication interface. The sensor data is used to determine an attribute of the object; and the determined attribute of the object is used to determine a plan to grasp and move the object.

A control system unit for a 3-dimensional (3D) object manufacturing system is disclosed herein that comprises one or more sensors and a controller. The one or more sensors are to sense 3D-objects manufactured in the manufacturing system in accordance with product specification data and to generate sensor signals representative for the sensed 3D-objects. The controller is to determine 3D-object characteristics of said sensed 3D-objects on the basis of said sensor data signals and to issue one or more corresponding control signals to control a system actuator unit so as to act on said sensed 3D-objects in accordance with their respective determined characteristics. The controller comprises a synthetic sensor data module to generate synthetic sensor data from product specification data of 3D-objects to be manufactured with the object manufacturing system, to therewith simulate sensor data for said 3D-objects to be sensed when manufactured. The controller further comprises a trainable classification module to be trained in a supervised manner with the synthetic sensor data. Therewith human assisted configuration efforts are obviated in that the improved control system unit does not require other input than the product specification data that was already available for the purpose of actually manufacturing the 3D-products to be identified.

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 cutting control method includes: a first step of accepting job identification information indicating a cutting target and cutting machine identification information indicating a type of a cutting machine; and a second step of specifying cut image data, and generating cutting operation data, wherein when the cutting machine identification information indicating a first cutting machine is accepted in the first step, first cutting operation data, and when the cutting machine identification information indicating a second cutting machine is accepted in the first step, second cutting operation data, and the first cutting operation data and the second cutting operation data are different from each other.

An improved method and device for to the automated production and/or qualification of devices and/or device components. The device generally comprises an improved manufacturing technology. The provided device substantially improves upon for automated manufacturing technology.