The present disclosure provides a carbonation preservation device that attaches to the mouth of an open container holding carbonated liquid. More specifically, the present invention relates to a device for preventing loss of carbonation from a carbonated liquid stored within a container by purging the trapped air above the remaining liquid within the container and replacing it with carbon dioxide or mixture of gases. When in place, the carbonation preservation device purges the air and other gases from the volume above the remaining carbonated liquid and fills the volume with a gas, such as carbon dioxide, or a mixture of gases, in order to pressurize the container and prevent the escape of carbon dioxide from the remaining carbonated liquid in the container.

The present disclosure provides a carbonation preservation device that attaches to the mouth of an open container holding carbonated liquid. More specifically, the present invention relates to a device for preventing loss of carbonation from a carbonated liquid stored within a container by purging the trapped air above the remaining liquid within the container and replacing it with carbon dioxide or mixture of gases. When in place, the carbonation preservation device purges the air and other gases from the volume above the remaining carbonated liquid and fills the volume with a gas, such as carbon dioxide, or a mixture of gases, in order to pressurize the container and prevent the escape of carbon dioxide from the remaining carbonated liquid in the container.

The present invention relates to a device and a method for decanting a beverage initially contained in one or more closed bottles into smaller containers. The device comprises an enclosure under an inert atmosphere, provided with an inlet port comprising receiving means, into which inlet port the neck of the bottles is fitted, and an outlet port through which the hermetically sealed containers are evacuated. The device contains an opening station for opening the bottles fitted into the receiving means, a collection vessel that collects the liquid flowing out of the bottles, a filling station for filling the containers from the collection vessel, and a sealing station for hermetically sealing the containers. In the method, the steps of opening and emptying the bottles, and of filling and hermetically sealing the containers, are all carried out under an inert atmosphere.

A controllable atmosphere collapsible container for perishable goods comprises a sealable bag accommodating the perishable goods and means for controlling atmosphere therewithin. The bag is mechanically connected to collapsible frame further comprising: (a) a concatenate rectangular carrying sub-frame; (b) concatenate supporting members releasably connectable to the rectangular carrying sub-frame. The bag is downwardly housed into the rectangular carrying sub-frame and configured for accommodating the perishable goods.

One embodiment of the present invention provides an apparatus for processing sealed plastic containers having a first headspace pressure. The apparatus may include: an open entry port or tunnel for continuously receiving containers; a sanitizer configured to sanitize outside surfaces of the received containers; a perforator configured to perforate or open a cap or seal of the containers within the apparatus; a sealer configured to seal the perforation or opening formed in the cap or seal of the containers; an open exit port of tunnel for continuously exiting the processed containers; and a conveyor system configured to transporting or convey the containers from the open entry port or tunnel, through and within the apparatus, to the open exit port or tunnel and away from the sanitized environment of the apparatus. The apparatus may be further configured to maintain a sanitized environment within the apparatus, perforator, and/or sealer.

The present disclosure provides a carbonation preservation device that attaches to the mouth of an open container holding carbonated liquid. More specifically, the present invention relates to a device for preventing loss of carbonation from a carbonated liquid stored within a container by purging the trapped air above the remaining liquid within the container and replacing it with carbon dioxide or mixture of gases. When in place, the carbonation preservation device purges the air and other gases from the volume above the remaining carbonated liquid and fills the volume with a gas, such as carbon dioxide, or a mixture of gases, in order to pressurize the container and prevent the escape of carbon dioxide from the remaining carbonated liquid in the container.

One feature pertains to a device that includes a main body having a bottle-receiving end that receives an end of a bottle having a mouth and forms an airtight seal between an exterior surface of the bottle and an interior air cavity of the main body. The device also includes an actuator assembly that drives a stopper securement device into a stopper positioned within the mouth of the bottle and retracts the stopper securement device to remove the stopper from the mouth of the bottle. The device also includes a vacuum pump that evacuates air out of the interior air cavity and the bottle's headspace after the stopper has been removed to create a vacuum within the headspace. The actuator assembly may also drive the stopper securement device and the stopper back into the mouth of the bottle to reseal the bottle while the headspace is under vacuum.

A system for evacuating and sealing containers filled with product, for example, food product, includes an enclosed, sealed housing wherein the pressure level and the atmospheric content can be controlled. A vacuum shroud is positioned in registry with a container entrance opening in the housing, the shroud connectible to a vacuum source and to a source of replaceable gas to replace the ambient air to be removed from the container. The shroud is advanceable to seal the container entrance opening and is retractable from the container entrance opening. A container transport system inserts the container through the housing entrance opening and into the shroud. Thereupon, a sealing system seals the housing from the ambient after the container has been inserted into the shroud. After the air in the container has been replaced with an inert gas and then the shroud retracted, a closure subsystem applies a cover to the evacuated container. Thereafter, an out feed subsystem removes the closed container from the housing while maintaining the atmospheric content and pressure level within the housing.

The present invention has been made in an effort to more assuredly substitute oxygen in a vial. A gas substitution apparatus according to the exemplary embodiment of the present invention includes: a first gas substitution unit which seals a periphery of an opening of a vial disposed in a gas substitution section, and guides a flow of a first substitution gas to be supplied into the vial; and a second gas substitution unit which is coupled to an upper side of the first gas substitution unit, and guides a flow of a second substitution gas to be supplied directly into the vial.

A work station (40) for a packaging line having an apparatus (4) for executing a simultaneous action on packages (10) of an alignment of packages with a tool (46); and a transfer mechanism (31) for the simultaneous transport of an alignment of packages to be processed (10b) to the apparatus (4) and of an alignment of processed packages (10c) from the apparatus (4). The alignments are arranged parallel to each other and the transport direction of the packages are perpendicular to the alignments, the transfer mechanism (31) thus having a first and a second transport group (31a, 31b), one of which hangs from two movable parts (60) of the transfer mechanism (31) which are movable on respective parallel planes of movement and which do not interfere with the vertical projection of the tool (46). A packaging line (101, 102, 103) with modular construction having such work stations.