A beverage packaging apparatus comprises a Refrigeration Assembly that keeps the beverage cold all the way to the fill head. The Refrigeration Assembly also allows manufacturers to fill off smaller beverage containers like kegs or larger storage tanks. The apparatus includes an integrated Container Loading Chute, and a Container Depalletizer having a scoop to depalletize containers. The Container Depalletizer integrates with the Container Loading Chute to provide for seamless flow for the Fill Head Assemblies and Seaming Assembly. The apparatus includes a unique integrated UV-C Sanitizing Station. The apparatus includes a conveyor with three fill head assemblies automated by smooth pneumatic actuation. Each fill head assembly has an integrated flow meter to provide precise fluid control. The apparatus includes a single pneumatic, rotary rack and pinion actuation that provides highly repeatable sealing of the container in a very small footprint without requiring sophisticated software to control the seaming operation. Finally, the apparatus includes rinse and dry assembly for the container and an innovative, integrated Accumulation Assembly to hold the completed beverage containers or packages.

A beverage packaging apparatus comprises a Refrigeration Assembly that keeps the beverage cold all the way to the fill head. The Refrigeration Assembly also allows manufacturers to fill off smaller beverage containers like kegs or larger storage tanks. The apparatus includes an integrated Container Loading Chute, and a Container Depalletizer having a scoop to depalletize containers. The Container Depalletizer integrates with the Container Loading Chute to provide for seamless flow for the Fill Head Assemblies and Seaming Assembly. The apparatus includes a unique integrated UV-C Sanitizing Station. The apparatus includes a conveyor with three fill head assemblies automated by smooth pneumatic actuation. Each fill head assembly has an integrated flow meter to provide precise fluid control. The apparatus includes a single pneumatic, rotary rack and pinion actuation that provides highly repeatable sealing of the container in a very small footprint without requiring sophisticated software to control the seaming operation. Finally, the apparatus includes rinse and dry assembly for the container and an innovative, integrated Accumulation Assembly to hold the completed beverage containers or packages.

Provided are a method and an apparatus for extruding into a tube and filling the tube at a high speed and simultaneously sealing the tube. Specifically provided is a method for producing a polymer tube, containing a liquid therein and being sealed at constant intervals, the method including an extrusion step of continuously melt-extruding a polymer material through a die into at least one tube, while feeding a liquid into the tube to obtain at least one liquid-containing tube; and sealing step of discontinuously pressing the at least one liquid-containing tube between a pair of pressurizing members at constant intervals to cause pressure-bonding before the tube solidifies, while continuously taking up the extruded tube.

Provided are a method and an apparatus for extruding into a tube and filling the tube at a high speed and simultaneously sealing the tube. Specifically provided is a method for producing a polymer tube, containing a liquid therein and being sealed at constant intervals, the method including an extrusion step of continuously melt-extruding a polymer material through a die into at least one tube, while feeding a liquid into the tube to obtain at least one liquid-containing tube; and sealing step of discontinuously pressing the at least one liquid-containing tube between a pair of pressurizing members at constant intervals to cause pressure-bonding before the tube solidifies, while continuously taking up the extruded tube.

A recyclable, thermally insulated shipping container is entirely constructed from organic fiber materials in such a manner that the container is curbside recyclable without separation of component materials. The container includes a corrugated cardboard outer box having a bottom wall, a plurality of sidewalls and a top wall, a corrugated cardboard inner liner assembly comprising a corrugated cardboard inner box having a bottom wall and a plurality of sidewalls, and a corrugated cardboard lid assembly. The outer box, inner liner assembly and lid assembly cooperate to create a plurality of thermally insulated cavities which are filled and uniformly packed with predetermined volumes of loose-fill cellulose (organic fiber) insulation to create a predetermined insulating value. The container provides a fully insulated six-sided product cavity to receive a temperature-controlled product. A portion of the product cavity may be filled with a PCM or other thermal media to provide a consistent temperature profile.

A method of packaging water-reactive aluminum may include directing at least one discrete object into a container, the at least one discrete object including an aluminum alloy, the aluminum alloy plastically deformed and non-recrystallized, introducing, into the container, a liquid metal alloy including one or more activation metals, enclosing the at least one discrete object and the liquid metal alloy with one another in the container to form a kit, for a predetermined period, exposing the kit to a heating environment, and agitating the at least one discrete object and the liquid metal alloy in the container in the heating environment during the predetermined period to form the kit into a packaged unit of water-reactive aluminum.

A method of packaging water-reactive aluminum may include directing at least one discrete object into a container, the at least one discrete object including an aluminum alloy, the aluminum alloy plastically deformed and non-recrystallized, introducing, into the container, a liquid metal alloy including one or more activation metals, enclosing the at least one discrete object and the liquid metal alloy with one another in the container to form a kit, for a predetermined period, exposing the kit to a heating environment, and agitating the at least one discrete object and the liquid metal alloy in the container in the heating environment during the predetermined period to form the kit into a packaged unit of water-reactive aluminum.

Devices for, and methods of, compressing a stented prosthetic heart valve are disclosed. The method including inserting a stented prosthetic heart valve having a self-expandable stent frame into a container, initiating a cooling element in the container, transferring heat through a thermal conductor to cool an interior of the container, reducing a temperature of the self-expandable stent frame while located within the container to a critical temperature of not greater than 8° C., and compressing an outer diameter of the stented prosthetic heart valve while the stented prosthetic heart valve is at the critical temperature.

Devices for, and methods of, compressing a stented prosthetic heart valve are disclosed. The method including inserting a stented prosthetic heart valve having a self-expandable stent frame into a container, initiating a cooling element in the container, transferring heat through a thermal conductor to cool an interior of the container, reducing a temperature of the self-expandable stent frame while located within the container to a critical temperature of not greater than 8° C., and compressing an outer diameter of the stented prosthetic heart valve while the stented prosthetic heart valve is at the critical temperature.

The invention comprises a method and apparatus for packaging a dispensable substance, including the steps of: placing a first product component into a container; adding a second product component into the container at an initial pressure of less than 1.31 atm, the container comprising a valve dispensing port; sealing the container; and increasing pressure in the container through a phase change of the second product component to a final pressure in the container, the final pressure at least 0.26 atm greater than the initial pressure. Optionally, the second product component warms in the container at least ten degrees Celsius and undergoes a phase change from a solid or liquid to a gas, which increases pressure in the container and functions as a propellant and/or as an expansion agent.