A ventilated container for produce includes a bottom, sidewalls extending upwardly from the bottom, and a rim having a flattened top surface. The sidewalls include at least one ventilation opening located proximate the rim of the container thereby permitting the rim of the container to be generally flat and uninterrupted. The location of ventilation opening(s) proximate the rim of the container allows the flow of rising ethylene gas within the container to exit near the top of the container improving ventilation within the container. A plastic film can be applied over the top of the container and is adhered to the container with an adhesive to form a secure and rigid seal between the film and the container. The flattened surface of the rim improves the adherence between a film and the container to enclose and seal the container, aids the rigidity of the container, and lessens the likelihood of the edges of the rim being bent or folded when pressure is exerted to protect produce provided within the container. Moreover, an aperture on the bottom of the container provides drainage of liquid from the container and allow air to flow.

A packaging apparatus suitable for containing and transporting a specified quantity of bananas or plantains includes a vented box and a plastic bag that includes laser microperforations located in target areas separated from each other by distances greater than their largest dimensions. When the bag is placed within the box, filled with bananas or plantains, and hermetically sealed, the microperforations and box vents allow for limited transmission of gases into and out of the bag to establish a modified atmosphere within the bag, and to allow ethylene ripening of the bananas or plantains. The target areas are located at the top of the bag, and also at the bottom of the bag, so that they are not occluded when the bananas or plantains are placed within the bag with their concave sides facing down.

A container apparatus having at least one containment member is disclosed that may include a bottom and at least one sidewall, an interior and an open end. The container may also include a flange that extends around a free end of the at least one side wall, and a plurality of wall members (or castellations) connected to/formed with/that extend from the flange. The plurality of wall members may be separated by ventilation apertures, with the plurality of wall members and the ventilation apertures extending around the perimeter of the free end. A sealing material, such as a removable film, may extend over the open end to enclose the containment member.

Packaging for sterile packaging a product, comprising a bag shaped body with two main surfaces that are mutually gas tight at at least part of their peripheral edges comprising a gas non-permeable material. At least part of the main surfaces comprises a gas permeable material part of a pore size that locks out harmful organisms and comprises a gas tight material part that is positioned between two peripheral edges that extend in a longitudinal direction and between the gas permeable material part and a peripheral edge that extends in a transverse direction.

My desiccator comprises a plurality of chambers in series communication with each other so a desiccating gas flows from one chamber into an adjacent chamber. A desiccating purge gas is introduced through an inlet into the desiccator's chambers at a predetermined flow rate, and a one-way bleed valve allows gas within the chambers to constantly flow from the desiccator while maintaining a positive pressure within the desiccator. A fan that constantly mixes and circulates the gas between the chambers as the desiccating purge gas is introduced into the desiccator, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. My method employs my desiccator to store items, wherein a dry, pressurized desiccating gas is introduced into the desiccator's chambers in a manner that constantly circulates the gas between the chambers as gas is slowly bled from the chambers, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. In my method the dew point of the desiccating gas is from 20 to 90 F. , the pressure of the desiccating gas is from 30 to 120 psi, and the average flow rate of the desiccating gas into the desiccator is from 0.25 to 4.0 cubic feet per minute.

A system for automatically sealing a plastic bag/enclosure over containers of biological materials carried on a pallet, comprising: a sealing system for automatically sealing a pallet bag enclosing a plurality of containers of biological materials wherein said pallet bag encloses the containers and an atmosphere surrounding the containers, the pallet bag optionally comprising at least one ACM and optionally including a reinforced portion. The pallet bag generally surrounds a number of flats or boxes on pallets containing fruits or vegetables that are sealed with or without a membrane to create an optimally suited atmosphere to control ripening, extend shelf-life, minimize microbial growth, maintain color, and maintain freshness.

The present invention includes an inner holder, an outer can, a first check valve and a second check valve. The inner holder includes a storage space. The outer can includes a slidable variable space for the inner holder to slide therein and an air channel for the slidable variable space to communicate with an exterior. The inner holder includes an air hole for the storage space to communicate with the slidable variable space. The first check valve is provided on the air hole and has an airflow direction towards the slidable variable space. The second check valve is provided on the air channel and has an airflow direction towards the exterior. The outer can is slidably moved outwards relative to the inner holder to suck out the air in the storage space and then slidably moved inwards relative to the inner holder to discharge air to the exterior.

A reusable container assembly including, a container having a plurality of tapered sidewalls extending substantially upwardly from a bottom surface forming an opening and an interior space. The bottom surface includes a plurality of feet extending substantially downwardly from the bottom surface. The assembly also includes a lid having a plurality of tapered sidewalls extending substantially downwardly from a top surface, the tapered sidewalls of the lid being configured to receive the tapered sidewalls of the container, such that the lid seals the opening of the container. The top surface of the lid also includes a plurality of raised corners extending substantially upwardly from the top surface, and the feet of the container are configured to receive the raised corners of the lid, when the lid is positioned beneath the container in a stacked configuration.

An inflatable packaging element is disclosed herein. The inflatable packaging element includes a first film ply and second film ply overlayed on the first ply, and a seal pattern. The seal pattern has a plurality of seals sealing the first and second plies to each other to define an inflation chamber between the first and second plies. The inflation chamber is inflatable with and configured to contain a fluid. An aperture extends through at least one of the first or second ply, and the seal pattern separates opposite side of the aperture from the inflation chamber.

My desiccator comprises a plurality of chambers in series communication with each other so a desiccating gas flows from one chamber into an adjacent chamber. A desiccating purge gas is introduced through an inlet into the desiccator's chambers at a predetermined flow rate, and a one-way bleed valve allows gas within the chambers to constantly flow from the desiccator while maintaining a positive pressure within the desiccator. A fan that constantly mixes and circulates the gas between the chambers as the desiccating purge gas is introduced into the desiccator, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. My method employs my desiccator to store items, wherein a dry, pressurized desiccating gas is introduced into the desiccator's chambers in a manner that constantly circulates the gas between the chambers as gas is slowly bled from the chambers, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. In my method the dew point of the desiccating gas is from 20 to 90 F, the pressure of the desiccating gas is from 30 to 120 psi, and the average flow rate of the desiccating gas into the desiccator is from 0.25 to 4.0 cubic feet per minute.