A method for reconciliation in a drug filling line includes providing a batch number relating to a predetermined batch of containers to be filled with a drug. Each one of the containers is marked with a unique identifier differentiating and/or identifying each container among others. Each unique identifier is stored and associated with the batch number by a processing and control unit, before starting the filling step of each container. Filled containers are flashed by at least one identifier reader to check correspondence between the batch number being processed and each filled container, in order to validate or reject in real time each container with respect to a predetermined batch being processed by the filling line.

A server and a controlling method therefor are provided. The server includes a communicator, a memory, and a processor configured to receive first log information related to a first material generated in a first facility among facilities, the first facility belonging to a first process for manufacturing a product through the communicator, generate an identifier (ID) regarding the first material, generate tracking information on the first material based on the first log information, assign the ID to the tracking information, receive pieces of second log information generated in a second facility among the facilities, the second facility belonging to a second process following the first process through the communicator, identify second log information corresponding to the first material among the pieces of second log information based on the first log information included in the tracking information, and update the tracking information based on the identified second log information.

The present application concerns a system for tracing a product item (102, 104) on a production line (100) comprising a control unit (10) and a timestamp counter (11), wherein the control unit (10) is configured to receive a product signal related to the product item (102, 104) from at least one peripheral device (12, 14, 16, 18, 20, 22, 24, 26). According to the invention, the control unit (10) is further configured to carry out the method steps of receiving a plurality of product signals each relating to a product item (102, 104) and a peripheral device (12, 14, 16, 18, 20, 22, 24, 26), generating a plurality of event signals, wherein each event signal is based on one of the product signals, arranging the event signals in a sequence corresponding to an order in which the product signals were received, and associating a timestamp generated by the timestamp counter (11) with the sequence.

A non-transitory computer-readable medium includes instructions that, when executed by processing circuitry, are configured to cause the processing circuitry to receive a first dataset associated with a mover system having a track and a plurality of mover assemblies independently movable along the track, identify a subset of the first dataset associated with a normal operating state of the mover system based on state data associated with the mover system, receive a second dataset associated with the mover system after receiving the first dataset and having a first set of differences from the subset of the first dataset, determine whether the second dataset is indicative of an anomaly state of the mover system based on a relationship between an anomaly signature dataset and the second dataset, and adjusting operation of the mover system in response to determining that the second dataset corresponds to the anomaly signature dataset.

A method serves to operate a transport system, in particular a multi-carrier system, that comprises a plurality of linear motors that are arranged in a row and have a guide track, a plurality of transport elements that can be moved along the guide track by means of the linear motors, and a plurality of stations along the guide track, wherein each of the transport elements is associated with one of the stations. The method has the following steps: generating an instance for each of the transport elements, generating a list for each of the stations, wherein the instance for each of the transport elements associated with the respective station is associated with the list, and wherein, within the respective list, the instance of each transport element is linked to the instance of the transport element directly ahead of the observed transport element and to the instance of the transport element directly behind the observed transport element, transferring a transport element from a first station to a directly following second station and inserting the instance of this transport element into the list of the second station if a transport job that goes beyond the first station is present for the transport element, wherein the transfer of the instance takes place in an event-controlled manner and independently of a transfer point if a predetermined transfer condition is fulfilled, and controlling the linear motors to execute travel jobs of the transport elements.

A method of improving board feature quality grading facilitates human check grader reaction to grading output. The method entails specifying, for application by an automatic grading system to the faces of boards passing through a scanning zone, a virtual grade expressed by a range of values that overlap values in two of successive standard rule-based grades representing higher and lower board feature qualities; producing a signal in response to detection of a board feature quality representing a virtual grade value of a board analyzed by the automatic grading system; indicating, in response to the signal, a virtual grading designation onto the board to alert a check grader to assess whether the board exhibits board feature quality that exceeds the lower board feature quality; and assigning to the board the standard rule-based grade representing the higher board feature quality whenever the check grader's assessment concurs with the virtual grade designation.

A simultaneous post-treatment detection process of a plurality of objects treated and positioned on a treatment base is provided, wherein the objects at first are coupled to a device identified by an identification code, and wherein the process comprises the fact of decoupling each object from the device to prepare the object for the treatment; positioning, before treatment, each object on a treatment base; associating, by recording by means of an electronic computer on a digital storage medium, the code of each device to an allocation position on the treatment base of a respective object at first coupled thereto by one or more phases selected from a phase of indicating the allocation position implemented by means of a visual support adapted to allow a user to display the allocation position on the base, and a phase of recognizing an outline, defined by each object and previously acquired by an optical instrument and associated to a respective said code, of an object on the base to determine the relative allocation position; detecting to the user the position of the object on the base for each code whenever the user recalls a code recorded on the storage medium, and wherein the recall is performed by visual inspection by the user if the association on the digital storage medium is reproduced by the computer as a graphic mapping viewable by the user, and/or by scanning a code by means of a scanning instrument operatively connected to the computer.

A machine learning device provided in a control unit observes, as state variables representing a current state of an environment, conveyance operation data indicating a state of a conveyance operation of a conveying machine and conveyance article state data indicating a state of the conveyance article, and acquires, as determination data, conveyance speed determination data indicating an appropriateness determination result relating to a conveyance speed of the conveyance article and conveyance article state determination data indicating an appropriateness determination result relating to variation in the state of the conveyance article. The conveyance operation data and the conveyance article state data are then learned in association with each other by using the state variables and the determination data.

A control apparatus for controlling a packaging machine that includes a conveyance mechanism for conveying an item to be packaged includes: an acquirer configured to acquire a detection result from a sensor for detecting an item to be packaged; a determiner configured to obtain elapsed time from a predetermined time point until when the item to be packaged is detected by the sensor, based on the detection result acquired by the acquirer, and determine a shift direction in which the item to be packaged is shifted from a predetermined position, based on the elapsed time; and a controller configured to control, for the item to be packaged for which detection is performed by the sensor, implementation of any one of downstream units that are downstream of a unit in which the detection is performed by the sensor, based on the shift direction that is determined by the determiner.

Tracing forged parts over their production process includes: capturing process parameters of a forging process; marking a workpiece with a first identifier; storing the captured process parameters and the first identifier in a database; reading the identifier from the workpiece produced in the previous process step; capturing process parameters during subsequent process steps; storing the process parameters of the subsequent process steps in the database for the read identifier, if legibility of the first identifier of the workpiece remains during the subsequent process step; marking the workpiece produced in the subsequent process step with a further identifier, if legibility of the first identifier of the workpiece does not remain during the subsequent process step of the production process; and storing the process parameters of the subsequent process step together with the further identifier and process parameters of the previous process steps and the first identifier in the database.