What is proposed is a closure unit consisting of a glass container (50) with external, circumferentially offset threaded elements (54, 55) on a container neck (52) of the glass container, and a closure cover made of sheet metal, wherein the closure cover (1, 2) has an encircling plastics layer (30; 30h, 30v) on the inside of the cover. The closure cover is pressed onto the container neck (52) and can be opened with a rotational movement via the threaded elements (54, 55) and a vertical section (30v) of the plastics layer. The container neck (52) has a horizontal end surface (52a) on which a horizontal section (30h) of the plastics layer rests under pressure in a sealing manner. A central region (11) of the closure cover passes with an adjoining, circumferentially oriented transition zone (11a, 11b, 11c) into an axially downwardly projecting skirt section (12) which ends in a roll-up region (21a, 21; 22). The plastics layer (30; 30h, 30v) is arranged on the inside of the cover in a manner adhering to the transition zone (11a, 11b, 11c) and the skirt section (12). An axial extent (h.sub.0) of the skirt section (12) and a radial dimension (b52) of the horizontally oriented end surface (52a) of the container neck (52) form a first ratio (v.sub.1) which is smaller than three.

The invention relates to a method for sealing an opening of a packaging, in which the packaging includes at least a peripheral wall with a peripheral top edge. The peripheral top edge forms the contour of the opening, including the following process steps: positioning a flexible film/foil layer over the peripheral top edge in such a way that the opening is completely covered and the film/foil layer overhangs beyond the peripheral top edge; heat-sealing the film/foil layer to the peripheral top edge of the packaging; folding the part of the film/foil layer overhanging beyond the opening towards the peripheral wall; heat-sealing the folded-over film/foil layer to the peripheral wall at a distance from the peripheral top edge, in which case a contact point of a device for heat-sealing the folded-over film/foil layer to the peripheral wall at a distance from the peripheral top edge does not move with respect to the film/foil layer during the heat-sealing, at least for as long as the contact point is in contact with the film/foil layer. The invention also relates to a device for heat-sealing according to the above method, and to a packaging manufactured in this way.

A high-speed continuous rotary type filling and packaging machine can identifies a defective filling head and a defective seal head and it also identify which part of a seal working surface in the seal head has a defect. In a sealing device of the high-seed continuous rotary type filling and packaging machine that covers a container body, which is filled with liquid contents, with a molded lid and seals the container body and the molded lid to produce a sealed container, a filling head number and a seal head number are inkjet-printed, desirably transparent ink, which can be read by irradiation of an ultraviolet ray, on a container body in which a seal working surface in the seal head and the top surface of the container molded lid are brought into press-contact and a positional relation between a seal working surface and the sealed container is fixed.

A packaging device for packaging material includes: a carry-in conveyor configured to carry in a food container along a conveyance direction; a carry-out conveyor configured to carry out the food container along the conveyance direction; a conveyor moving mechanism configured to move at least one of the carry-in conveyor or the carry-out conveyor; a packaging material pressing mechanism configured to press a band-shaped packaging material against the food container conveyed between the carry-in conveyor and the carry-out conveyor and to attach the band-shaped packaging material to the food container; and a control device configured to cause the conveyor moving mechanism to move at least one of the carry-in conveyor or the carry-out conveyor to thereby form an attachment space between the carry-in conveyor and the carry-out conveyor where the packaging material pressing mechanism attaches the band-shaped packaging material to the food container.

A system for assembling a container and closure comprising an expanding collet which has a plurality of pivoting collet segments, each configured to simultaneously pivot radially outward about a pivot point and comprising. The collet comprises a lip that is engagable with the rim of the open end of the container and an angled tip positioned radially inward from the lip and shaped to press a countersink portion of the closure against an interior wall of the container as the collet segments pivot radially outward. As the container and the chuck are brought together, the rim engages with the lips of the collet segments and causes the angled tips of the collet segments to pivot outward toward the interior wall of the container, thereby pushing the countersink portion of the closure against the interior wall of the container.

An aerosol product comprising an aerosol container comprising a container body and an aerosol valve fixed to an opening of the container body, and an aqueous concentrate and a propellant being filled in the aerosol container, wherein the aqueous concentrate comprises an active ingredient having reactivity with oxygen, and an inert ingredient is present in at least a part of an injection passage of the aerosol valve, even though the aqueous concentrate comprising an active ingredient having reactivity with oxygen is filled, oxidation of the active ingredient is inhibited in the aerosol valve, and an aerosol product that can be stored stably for a long period of time and a method for manufacturing the same can be provided.

The present invention relates primarily to vacuum preservation of items, and particularly to a flexible vacuum sealing adapter for use with food storage systems, wherein the flexible vacuum sealing adapter includes a flexible container interface, the flexible container interface having circumferential sidewall and an upper sealing wall, the flexible container interface being configured to seal an opening of a storage container, a vacuum port assembly being provided through the flexible container interface, the vacuum port assembly including a vacuum interface and a check valve configured to provide unidirectional flow of air from within the storage container to an exterior environment; and a deflection interface, the deflection interface including one or more input tabs, wherein a force input to the one or more input tabs results in an elastic deformation of the flexible container interface so as to cause an increase in diameter of the circumferential sidewall.

An aluminum bottle outsert includes an annular inner surface configured to be received and supported on an upper neck portion of an aluminum bottle. The outsert also includes an annular outer surface that has a threaded portion adapted to receive a wine bottle screw top capping assembly.

A fully compostable beverage capsule may be produced by improving the seal strength between the capsule and its lid. In this invention, a number of protruding “spikes” are added to the upper and/or lower edges of the capsule. The lidding is then attached to the capsule via an energetic welding process, such as ultrasonic welding. The protruding “spikes” are deformed during this welding, increasing the surface area contact between the capsule and its lidding. Acting similarly to rivets, these spikes will improve the strength of the seal that forms between the lidding and the capsule.

A fully compostable beverage capsule may be produced by improving the seal strength between the capsule and its lid. Additionally, the lid itself may be made more resistant to the stress that occurs during brewing. In this invention, the lidding material is cut one or more times to produce a pattern similar to the blades of a pinwheel. The sections or “blades” are then overlapped and energetically welded to one another and joined to the beverage capsule. In this process, the double thickness of lidding material improves the seal between the lidding and the capsule. Each “blade” of the lidding has its own point of attachment to the capsule, which helps to isolate any stress that may occur during the beverage brewing process. As a result, the lidding as a whole remains securely attached to the capsule, even if one or two blades experience sufficient stress to trigger delamination.