A cap 120 for a bottle 110 includes an upper portion 130 and a lower portion 140. The upper portion is configured to be positioned on an exterior of the bottle when the cap is engaged with the bottle. The lower portion is configured to be positioned at least partially within the bottle when the cap is engaged with the bottle. A lower end of the lower portion includes a first perimeter portion 150 and a second perimeter portion 151. A first distance between the upper portion and the first perimeter portion is different than a second distance between the upper portion and the second perimeter portion.

Provided is a cap of a container. The cap has an image formed thereon and includes a first part and a second part. When the cap is opened, the first part is separated from a container body of the container, and the second part remains on the container body of the container. The image is formed on a region straddling both a side surface of the first part and a side surface of the second part.

Provided is a cap of a container. The cap has an image formed thereon and includes a first part and a second part. When the cap is opened, the first part is separated from a container body of the container, and the second part remains on the container body of the container. The image is formed on a region straddling both a side surface of the first part and a side surface of the second part.

The invention describes a novel method of transducing a force input into a perpendicularly directed advance of a geared component. This simple mechanism allows for the implementation of latches, accelerometers, tilt sensors, and counters that are uniquely inexpensive, robust, compact, and easy to implement, since they are able to rely on purely mechanical operation.

The invention describes a novel method of transducing a force input into a perpendicularly directed advance of a geared component. This simple mechanism allows for the implementation of latches, accelerometers, tilt sensors, and counters that are uniquely inexpensive, robust, compact, and easy to implement, since they are able to rely on purely mechanical operation.

A metal bottle assembly adapted for use on a plastic bottling includes a metal bottle with an outsert assembled on the neck portion of the bottle. The outsert may be constructed from plastic material and may be fixed to the bottle using an interference fit. The outsert enables the bottle to be placed on a plastic bottling line with minimal or no modifications to the bottling line. The outsert also ensures that the metal bottle is not damaged by handling on the plastic bottling line. In some embodiments, the outsert is designed to elastically deform as it is pressed on the neck of a pre-formed metal bottle and therefore create the interference fit between the outsert and the bottle. In some embodiments the outsert is retained on the neck of the bottle through the interference fit alone.

A metal bottle assembly adapted for use on a plastic bottling includes a metal bottle with an outsert assembled on the neck portion of the bottle. The outsert may be constructed from plastic material and may be fixed to the bottle using an interference fit. The outsert enables the bottle to be placed on a plastic bottling line with minimal or no modifications to the bottling line. The outsert also ensures that the metal bottle is not damaged by handling on the plastic bottling line. In some embodiments, the outsert is designed to elastically deform as it is pressed on the neck of a pre-formed metal bottle and therefore create the interference fit between the outsert and the bottle. In some embodiments the outsert is retained on the neck of the bottle through the interference fit alone.

A cap for sealing a mouth of a crown finish or threaded crown finish glass bottle, the crown cap is formed by a circular wall, a curved wall perimetrical to the circular wall, and a closure skirt that descends radially downward and outward from the curved wall and formed by a plurality of interleaved protrusions and depressions, the curved wall has a radius of curvature from 1.5 mm (0.590551 in) to 1.9 mm (0.748031 in) and an arc less than 86°; the crown cap is formed from a circular sheet cutout with a diameter from 33.4949 mm (1.3187 in) to 35.5346 mm (1.399 in), resulting in a crown cap with an axial height less than the axial height of a crown cap from the state of the art.

A cap for sealing a mouth of a crown finish or threaded crown finish glass bottle, the crown cap is formed by a circular wall, a curved wall perimetrical to the circular wall, and a closure skirt that descends radially downward and outward from the curved wall and formed by a plurality of interleaved protrusions and depressions, the curved wall has a radius of curvature from 1.5 mm (0.590551 in) to 1.9 mm (0.748031 in) and an arc less than 86°; the crown cap is formed from a circular sheet cutout with a diameter from 33.4949 mm (1.3187 in) to 35.5346 mm (1.399 in), resulting in a crown cap with an axial height less than the axial height of a crown cap from the state of the art.

The presently disclosed subject matter is directed to a closure assembly for use with a container (e.g., an aerosol can). The closure assembly includes a skirt and a protective cap. In some embodiments, a lock feature temporarily attaches the protective cap to the container and increases a force required for a user to remove the protective cap. In some embodiments, an inner lock opening of the skirt is configured to be registered with an outer lock opening to receive a locking element therethrough. In some embodiments, a set screw is positioned in the skirt to selectively allow or inhibit relative rotation between the skirt and the protective cap. In some embodiments, a biasing element selectively allows or inhibits engagement of threads of the protective cap with the threads of the skirt depending upon application of an axial force to overcome a biasing force of the biasing element.