A fin sealer and method to seal a radially outwardly directed fin of a tubular web structure by directing the fin through a nip between a first and a second fin sealing rollers while communicating heat to the fin through at least one of the fin sealing rollers is provided. The fin sealer is configured to maintain a nominal face-to-face relation between an outer annulus of the first fin sealing roller and an outer annulus of the second fin sealing roller with a flexible connection between a hub element of the second fin sealing roller with the outer annulus of the second fin sealing roller.

Method for operating a container treatment system (1), wherein containers are treated in a first predefined fashion with a first treatment device (2) of this container treatment system (1), are subsequently transported from this first treatment device (2) to a second treatment device (4) of the container treatment system (1) and are subsequently treated in a second predefined fashion by the second treatment device (4), wherein a first multiplicity of first reference characteristic values (RK1), which are characteristic of the treatment of the containers (10) the first treatment device (2), is recorded by means of first sensor devices (22a, 24a), and a second multiplicity of second reference characteristic values (RK2), which are characteristic of the treatment of the containers (10) with the second treatment device (4), is recorded by means of second sensor devices (42a, 44a), and wherein these reference characteristic values (RK1, RK2) are stored in a memory device (16). According to the invention, the reference characteristic values (RK1, RK2) are registered with a time value which is characteristic of the chronological occurrence of the respective reference characteristic value (RK1, RK2), and a multiplicity of test characteristic values (PK1, PK2) is recorded, and at least one information item (I), which is characteristic of the determination of a present or future fault state of the system, is output on the basis of comparison between at least one of these test characteristic values (PK1, PK2) and at least one reference characteristic value (RK1, RK2).

A combined weighing system 1 includes a first X-ray inspection device 20, a combined weighing device 40, a bag making and packaging device 50, a weight inspection device 60, a second X-ray inspection device 70, and a management device 90 that manages each device. The management device 90 revises a weight conversion table of the first X-ray inspection device 20 and a correction value of the combined weighing device 40 based on an average value of weights of products B, which is calculated from a result of inspection over a certain time period in the weight inspection device 60.

Inspection of a shape-fixed medicine is performed before packing. A medicine inspection assistance device includes: a medicine support part for rotatably supporting a shape-fixed medicine by a first rotating roller and a second rotating roller, and a medicine imaging part having an imaging means for imaging the shape-fixed medicine supported by the medicine support part from above. The medicine support part is configured such that a contact position between the first rotating roller and the shape-fixed medicine is located above the second rotating roller and the contact position is closer to an axis of the first rotating roller than a gravity center position of the shape-fixed medicine.

Processing raw data stored in an historian device for determining an amount of products passed through a process element in a process control environment is described. A count value is incremented by a counter at a rate at which products pass through the process element. The count value rolls over to zero when the count value reaches a rollover value R. An historian device periodically receives count value data points from the counter. A deadband value D is set in the historian device for distinguishing between rollovers, resets, and reversals. A client device queries the historian device for an amount of products passed through the process element for a timeframe. The historian device selects a set of count value data points from within the queried timeframe. The historian device determines, based on the selected data points and their quality, an amount of products passed through the process element.

Processing raw data stored in an historian device for determining an amount of products passed through a process element in a process control environment is described. A count value is incremented by a counter at a rate at which products pass through the process element. The count value rolls over to zero when the count value reaches a rollover value R. An historian device periodically receives count value data points from the counter. A deadband value D is set in the historian device for distinguishing between rollovers, resets, and reversals. A client device queries the historian device for an amount of products passed through the process element for a timeframe. The historian device selects a set of count value data points from within the queried timeframe. The historian device determines, based on the selected data points and their quality, an amount of products passed through the process element.

Various systems, methods, and programs embodied in computer-readable mediums are provided for determining sizes of packaging in a packaging suite and generating the new packaging. The packaging may be used, for example, in the shipping of items. Data may be received that describes bounding boxes corresponding to collections of items shipped to customers. The sizes of the packaging in the packaging suite may be determined based at least in part upon the data that describes the bounding boxes.

Various systems, methods, and programs embodied in computer-readable mediums are provided for determining sizes of packaging in a packaging suite and generating the new packaging. The packaging may be used, for example, in the shipping of items. Data may be received that describes bounding boxes corresponding to collections of items shipped to customers. The sizes of the packaging in the packaging suite may be determined based at least in part upon the data that describes the bounding boxes.

An apparatus for dispensing and packaging dosed quantities of solid drug portions is provided. The apparatus includes multiple dosing stations, each dosing station having an output opening for dispensing solid drug portions, a collector for collecting dosed quantities of solid drug portions dispensed by the dosing stations and forwarding the dosed quantities of solid drug portions to a packager, and multiple fall ducts configured to guide the solid drug portions from the output openings to the collector, each fall duct having an outlet and a number of inlet openings, the output openings of the dosing stations being aligned with the inlet openings of the fall ducts when a fall duct is positioned adjacent to a column of dosing stations. Each fall duct includes a first part and a second part detachably connected together.

An apparatus for dispensing and packaging dosed quantities of solid drug portions is provided. The apparatus includes multiple dosing stations, each dosing station having an output opening for dispensing solid drug portions, a collector for collecting dosed quantities of solid drug portions dispensed by the dosing stations and forwarding the dosed quantities of solid drug portions to a packager, and multiple fall ducts configured to guide the solid drug portions from the output openings to the collector, each fall duct having an outlet and a number of inlet openings, the output openings of the dosing stations being aligned with the inlet openings of the fall ducts when a fall duct is positioned adjacent to a column of dosing stations. Each fall duct includes a first part and a second part detachably connected together.