A cover (200) and a manufacturing method therefor. The cover (200) comprises a dispensing port (212), a detachable plug (250) that is located at the peripheral edge (230) of the cover (200) and integrally formed with the cover (200), and a recess (222). When a sealing structure is formed between the cover (200) and a cup (100), the dispensing port (212) is used for providing an outlet for contents present in the cup (100). The detachable plug (250) comprises a protrusion (255), and the protrusion (255) is used to form another sealing structure between the protrusion (255) and the dispensing port (212). The recess (222) is configured to be detachably coupled with the protrusion (255) so as to keep the detachable plug (250) in the vicinity of the cover (200) when the detachable plug (250) is not in use.

A packaging for drinking water/minerals or other liquid substances for individualized ice formation is disclosed, which provides for areas of expansion of the liquid for its transformation into ice and its tubular shape without damaging the packaging, i.e. the weak sealing (3) which provides for the expansion/expansion, which will be broken at the proposed end(s) and the expansion generated in the change of state from liquid to solid will be assimilated normally by the package conformation, but limited by the strong sealing (2) and stronger (4), avoiding early package rupture, ensuring its integrity, either for storage or after frozen for consumption.

A temperature insulated packaging system includes a container having interior surface bounding an interior volume and a liner disposed within the interior volume and at least partially bounding a compartment configured to receive an item for temperature insulated shipping. The liner includes a first sleeve made of cellulose material and at least partially bounds a channel. The first sleeve has an outside wall disposed adjacent to the container and an opposing inside wall disposed adjacent to the compartment configured to receive the item for shipping, the channel being disposed between the inside wall and the outside wall. At least one insulation sheet is disposed within the channel of the first sleeve, the at least one insulation sheet being made of a cellulose material and having a plurality of recesses formed thereon.

The presently disclosed subject matter is generally directed to a packaging film constructed from water-dispersible and/or biodegradable compositions. Particularly, the disclosed film comprises a first layer constructed from one or more water-dispersible materials, such as water-dispersible paper. The film further comprises a second layer constructed from one or more biodegradable materials, such as poly(hydroxyalkanoate). The first and second layers can be constructed to form a packaging material used to enclose a wide variety of products, including liquids and moisture-sensitive solids. Advantageously, the disclosed film (and associated packaging materials) are dissolvable in water and/or biodegrade when exposed to landfill conditions and/or water.

A container includes: a pulp-formed shell configured to contain a material therein, the pulp-formed shell having an opening through which the material may pass, the pulp-formed shell being formed from a first material; and, a collar having one or more engagement features configured to engage at least a portion of the pulp-formed shell by pinching, indenting, deforming, or any combination of pinching, indenting and deforming, at least a portion of the pulp-formed shell, the collar being formed from a second material.

Disclosed is a biodegradable, compostable and thermoshrinking film for packaging perishable goods, including a base structure substantially permeable to light radiation and including a first layer 10 μm thick, to directly contact the goods, and consisting of 89% in weight Mater-Bi® EF51L, 10% in weight BioGranic™ 3112 and 1% in weight Mater-B® master MEE. A second layer, overlapping the first, has a thickness equal to the one of the first layer and consists of 50% in weight Mater-Bi® EF51L and 50% in weight Mater-Bi® DF51A0. A third layer, overlapping the second, has a thickness equal to the one of the first layer and consists of 99% in weight Mater-Bi® EF51L and 1% in weight Mater-Bi® master MEE. A barrier layer including aluminum and/or aluminum oxide and/or silicon oxide and having a thickness ≤0.1 μm overlaps the third layer.

A biodegradable whole leaf pillow tea bag is provided, along with a system and method for manufacturing biodegradable whole leaf pillow tea bags. The method for manufacturing the whole leaf pillow tea bags includes the steps of providing a biodegradable infusion substrate having two opposing edge; creating a sleeve from the biodegradable infusion substrate by infusing the two opposing edges of the substrate together and closing the sleeve at its bottom; placing whole leaf tea in the bottom of the sleeve; vertically feeding the sleeve containing the whole leaf tea into a heat sealing machine that will, at predetermined intervals create heat seals across the sleeve to create pillow bags; cutting the pillow bags from one another across the heat seal. In one example, the biodegradable infusion substrate may contain hemp and/or the whole leaf tea may be infused with CBD oil or other supplements. The same method of manufacturing may be used to create a biodegradable pillow bag containing coffee.

A convertible beverage container package having an integrated cooler compartment is provided that is sized to contain a number of cans in a box shape during transit, storage, and sale and which can be converted to a portable cooler configured to receive ice for cooling the cans contained therein. The shape of the convertible beverage container package allows a compact package for storage and transport, which can be selectively expanded to receive ice. In some cases, the received ice may surround two or more sides of the beverage cans. In one case, the shape of the convertible beverage container package may direct ice inside the package to contact the canned beverages on at least three sides.

A compostable single-use container generally includes a substantially planar lid component and a tray component. The lid component has a top surface and a bottom surface. The tray component has a generally planar top surface adhesively bonded to the bottom surface of the lid component with a sustainable adhesive, and a chamber configured to store an object. The tray component is thermoformed fiber comprising at least one of recycled cardboard, hemp straw, and cannabis straw. The lid portion comprises at least one of a natural-fiber card stock and a compostable sticker.

Present invention relates to a packaging box for fruit, berries and vegetables, and a method for packing fruit, berries and vegetables, where the packaging box may be made of environmental friendly materials, such as cardboard. The packaging box comprising at least four walls (2,3,11,12) comprising at least a front wall (3) two opposing side walls (11,12) and a back wall (12), a bottom (13), and a lid (4), wherein a first side (41) of the lid (4) is connected to the upper end of one of the back wall (2) and front wall (3), and a second side of the lid, opposite the first side (41), being adapted for connecting to the outside of a side wall.