Provided is packaging machine with a sealing station that includes a mold with an upper tool and a lower tool facing each other and suitable for cooperating with one another in an operative position of the mold, between which there is delimited an inner area. The lower tool includes a cavity that is configured to receive a tray. A gas injection opening is located adjacent to a first side of the cavity and communicated with the inner area. The upper tool includes a sealing tool and an actuator device facing an actuation region of the lower tool defined between the first side of the cavity and a contact location of the upper and lower tools, and being closer to the lower tool than the sealing tool.

In a transfer device and a process for discrete elements, fed in a line with a predetermined spacing, variations in the dimensions of the discrete elements resulting in a variation in a release spot included in a release segment, are absorbed by an alignment of the receiving elements. A transport device of the transfer device has receiving elements, each configured to receive a respective discrete element and moving along a transport path at a predetermined speed. The discrete elements are transported on a release device of the transfer device along a release path with a linear development. The release path has a release segment intersecting the transport path at a receiving segment of the transport path. The transport device includes a moving mechanism for the receiving elements to align the receiving elements at the receiving segment, where the release segment is superimposed on the transport path at the receiving segment.

A thermoforming packaging machine includes a forming station for thermoforming troughs in a film web, a filling path for filling products into the troughs, a sealing station for sealing the troughs, a chain guide for guiding a transport chain for the film web, a transverse cutting device for cutting the film web in a direction transverse to the transport direction, a longitudinal cutting device for cutting the film web in the transport direction, and a control device for controlling processes running on the thermoforming packaging machine. The transverse cutting device comprises a film punch, an adjustment drive which can be controlled by the control device for closing and opening the film punch, and a detection unit which is connected to the control device and which has at least one sensor which is configured to detect, per processing cycle, a force progression occurring at the film punch during opening and closing.

A thermoform packaging machine comprising a forming station, a sealing station, and a cutting station for separating sealed packaging troughs from one another. The cutting station may comprise at least one cutting unit which is adapted to be positioned within the cutting station at different positions in the production direction. The cutting station may comprise a support that supports bottoms of the sealed packaging troughs conveyed into the cutting station for the purpose of separation from below. The support may comprise a plurality of support elements arranged in a horizontal bearing plane and which form a gap at a position in the support at which a cutting operation takes place according to the position of the cutting unit. The gap may be repositioned by moving the support elements to different positions to position the gap to accommodate a different position of the cutting unit within the cutting station.

A curl correcting device (1) includes a pressing unit (12) disposed on a +Z direction side of a blister film, and pressing, by a pressing member (121), an area including a pocket in the blister film and including both end portions of the blister film in an X-axis direction; and a support member (131) supporting the blister film in a state of abutting on a −Z direction side on both sides of an area pressed by the pressing member (121) in a Y-axis direction of the blister film. A recess (121a) having a width in the X-axis direction greater than a width in the X-axis direction of the pocket and penetrating the pressing member (121) in the Y-axis direction is formed at a location corresponding to the pocket of the blister film on the −Z direction side of the pressing member (121).

A method for dividing a blister strip having a plurality of blister-packaged drugs apportioned into separate sections of the blister strip is provided. A blister strip with a substrate having a plurality of depressions for drug portions is provided and an image of the substrate is generated by a 3D-sensor device, the image including depth information. A control device evaluates the image with image analysis. Based on the analysis results, an arrangement of the depressions is determined and control signals for a separating device are generated. The blister strip is then divided into a plurality of blister strip parts based on the control signals.

A deep-drawing packaging machine that includes a sealing station and a method for changing the sealing frame together with the sealing plate at the sealing station. The sealing station includes a sealing plate and a sealing frame. The sealing plate may be releasably coupled to an upper sealing tool part, and the sealing frame may be slidably removable at a lower sealing tool part. The sealing frame may be slidable on rails. The sealing frame may include one or more centering aids for aligning the sealing plate with respect to said sealing frame during removal thereof. The centering aids may be displaceable underneath a film web by the upper sealing tool part during the clamping of the film web between the sealing frame and the upper sealing tool part.

A method for the production and filling of an application package for a liquid pharmaceutical product. A thermoforming film made of thermoplastics laminated together is heated in order to plasticize the thermoforming film at least in partial areas. The plasticized areas are thermoformed in a mold in order to form a chamber for the liquid pharmaceutical product and a tube-shaped application duct opening into this chamber, with the chamber and the application duct being enclosed by a non-thermoformed, essentially flat bonding area of the thermoforming film. The liquid pharmaceutical product is filled into the chamber, and the chamber and the application duct are sealed by covering the thermoformed and filled thermoforming film with an essentially flat covering film. The covering film is directly bonded to the bonding area of the thermoforming film by thermal ring sealing, enclosing the chamber and the application duct.

An apparatus for producing packages of infusion products, such as a bag filled with a dosed quantity of a product, a tag and a length of thread attached at opposite ends to the bag and to the tag respectively, includes a forming group of the filled bag, a feeding group of the formed bag and of the tag, a cutting and feeding group of the length of thread, and a sewing head of the length of thread to the bag and to the tag.

The invention relates generally to a sanitizing device that may comprise of an enclosure, a conveyor module, a plurality of sanitizing light sources, and possibly a sealing module. Objects that need to be sanitized may be transported or placed inside the enclosure and can be exposed to sanitizing lights from a plurality of sanitizing light sources. After the exposure to the sanitizing lights, the objects may convey out of the apparatus or go through a sealing module before exiting the enclosure. The conveyor module of the sanitizing device may be driven by torque created by an exterior conveyor belt or a motorized mechanism integrated within the apparatus.