Product transport containers are disclosed. Such containers can provide one or more advantages compared to existing containers. For example, product transport containers described herein can maintain a product at a desired temperature for an extended period of time, including without the use of an active heating or cooling component. Such product transport containers described herein may also provide improved breathability, thermal insulation, and/or mechanical strength or dimensional stability. Such containers can include a plurality of walls defining an interior volume and a selectively openable side permitting movement of the product into and out of the interior volume of the container. The walls can be formed from a thermoformed non-woven fabric.

A support panel for use in protecting a piece of merchandise packaged within a bubble portion adhered to a card portion. The support panel includes a support enclosure defining a receptacle that is sized and configured to house the bubble portion therein and to generally conform to a number of corresponding exterior surfaces of the bubble portion. The support panel also includes a planar portion that extends outward from a periphery of the receptacle that is sized and configured to be disposed against the card portion when the bubble portion is housed within the support enclosure.

Disclosed are daucus-based oxygen scavenging compositions and materials, particularly of the carrot species, and their methods of use in containers and packaging of oxygen sensitive products. Further disclosed are daucus-based oxygen scavenging materials used in combination with tea-based oxygen scavenging compositions. Such compositions, materials and containers are of use for preserving the shelf-life of a myriad of products such as foods, pharmaceuticals, cosmetics, tobacco and cannabis.

A crate includes a base and a plurality of walls extending upward from the base. A plurality of ventilation channels are formed in the base. The ventilation channels project upward relative to an upper support surface of the base. The ventilation channels include apertures therethrough.

A receptacle is designed for a chamber for an active substance. The receptacle includes two main elements. A first element is a transverse wall with a first main side facing an interior of the chamber, and a peripheral wall formed with the first main side of the transverse wall. A second element includes a bottom wall and a sheath extending from the bottom wall. The peripheral wall and the sheath surround one another and are in contact with each other so that the chamber is formed between the bottom wall, the transverse wall, the peripheral wall and/or the sheath. At least one ventilation groove is provided between the peripheral wall and the sheath form a ventilation channel connecting the chamber with the outside atmosphere.

A receptacle forming a chamber partially filled with an active substance, wherein the receptacle is a body and a cap which closes the body. The cap includes a top wall with a first main side facing an interior of the chamber and a skirt formed with the first main side of the top wall. The body includes a bottom wall and a sidewall. The skirt and the sidewall surround one another in contact with each other. The walls surrounding the chamber include the bottom wall, the top wall and either the skirt or the sidewall. At least one ventilation path is provided between the skirt and the sidewall, such that the ventilation path connects the chamber with the outside atmosphere.

A thermally insulated package having an outer container formed of fiberboard and comprising a base wall, a peripheral side wall and a closable top wall. The base wall, side wall and top wall defining a container interior. An insert is fitted within the container interior and formed of fiberboard. The insert comprising a floor panel and a peripheral side panel defining an insulated compartment and open top. The floor panel and side panel are each associated with the base wall and side wall of the container respectively. A thermal insulating layer to be interposed between the outer container and the insert, said insulating layer including wool fibers.

A method is described herein for slowing, inhibiting, and/or preventing the growth of microbes, or for killing microbes, within and/or on a product/good that is stored in a package. The method can include applying a film cover over a perforated portion of a package and securing the film cover to the package at the perimeter of the perforated portion with an adhesive or by heat stacking. The film cover can include a material for changing the atmosphere within the package. The package may be an existing pre-perforated package, or may be a package that requires perforation. If the package requires perforation, the method can further include perforating at least a portion of the package prior to positioning the film cover over the perforated portion. The film cover can be formed of a three-phase material or other material.

According to an example aspect of the present invention, there is provided a box-shaped package, comprising: a base, and a cover configured to be placed on the base to close the package, wherein in a closed configuration of the package, the interface between the base and the cover is gas-tight; the base and/or the cover comprise one or more gas-permeable zones which are capable of passing gases, such as air, into and out from the package, particularly in the closed configuration.

A package arrangement comprising a structure formed by a plurality of layers including an outer layer formed of a polymer material, one or more interior layers formed of a semi-aromatic polyamide composite material, and an inner layer formed of a polymer material, and an amount of water contained within the structure, the water including an amount of ozone dissolved therein, wherein the interior layer of the structure is configured to absorb oxygen and induce the degradation of the ozone.