A method of and apparatus for accelerating the cooling of a beverage can and/or ice tray utilizing at least one body that presents a density and thermal conductivity, defines a standard beverage can and/or ice tray receiving receptacle configured to form a minimum contact surface area of engagement
A method of and apparatus for accelerating the cooling of a beverage can and/or ice tray utilizing at least one body that presents a density and thermal conductivity, defines a standard beverage can and/or ice tray receiving receptacle configured to form a minimum contact surface area of engagement with at least one can and/or tray, and preferably further defines a series of thru-holes, so as to promote accelerated cooling through conduction, convection within a compartment.
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1. A rapid cooling dock adapted for use within chilled air encased within a compartment, and for accelerating the cooling of a standard beverage can comprising a continuous sidewall, wherein the air presents an average temperature, the sidewall presents an outside surface area, and the can and the a
1. A rapid cooling dock adapted for use within chilled air encased within a compartment, and for accelerating the cooling of a standard beverage can comprising a continuous sidewall, wherein the air presents an average temperature, the sidewall presents an outside surface area, and the can and the air cooperatively produce a first heat transfer rate from the can and to the air when the can is placed within the air, said dock comprising: at least one body having a first discontinuous surface, said first surface defining a receptacle, said receptacle being open, so as to enable the lateral placement and removal of the can, and said receptacle being cooperatively configured with the sidewall to present a contact surface area of engagement with at least five percent of the outside surface area when the can is placed within the receptacle,said body defining a second surface opposite and parallel to the first surface, wherein said second surface is flat, so as to present a stable base when placing the body within the compartment,said at least one body presenting a mass, density, and thermal conductivity operable to cause heat transfer from the can and to said at least one body at a second heat transfer rate greater than the first heat transfer rate when the can is placed within the receptacle and said at least one body is at the average temperature. 2. The dock as claimed in claim 1, wherein the second heat transfer rate is at least fifty percent greater than the first heat transfer rate. 3. The dock as claimed in claim 1, wherein the sidewall presents a width, the can presents a cylinder defined by a first radius and a first length, and the receptacle defines a concavity defined by a second radius generally equal to the first radius plus the width of the sidewall and a second length greater than the first length. 4. The dock as claimed in claim 1, wherein the dock is affixed to or composes the compartment, such that the receptacle composes an inner surface of the compartment. 5. The dock as claimed in claim 4, wherein the receptacle is cooperatively configured with the can to present a contact surface area of engagement with at least ten percent of the outside surface area of the can, when the can is placed within the receptacle. 6. The dock as claimed in claim 1, wherein the receptacle is cooperatively configured with the can to present a contact surface area of engagement with at least 20 percent of the outside surface area of the sidewall, when the can is placed within the receptacle. 7. The dock as claimed in claim 1, wherein said at least one body is formed of a metallic material. 8. The dock as claimed in claim 7, wherein said at least one body is formed of aluminum or an aluminum alloy. 9. The dock as claimed in claim 7, wherein said at least one body is formed of steel. 10. The dock as claimed in claim 7, wherein said at least one body is treated to prevent rust, when placed within the air. 11. The dock as claimed in claim 1, wherein said at least one body is detached from the compartment, so as to be manually removable therefrom. 12. The dock as claimed in claim 1, wherein a cuboid body defines first and second receptacles configured to engage first and second cans comprising sidewalls having differing radii, outside surface areas, and/or lengths respectively, and said first and second receptacles are each configured to form a contact surface area of engagement with at least five percent of the outside surface area of the respective sidewall. 13. The dock as claimed in claim 12, wherein said first and second receptacles are defined within the first surface. 14. The dock as claimed in claim 12, wherein the body defines first and second opposite surfaces, and the first and second receptacles are defined in the first and second opposite surfaces, respectively. 15. The dock as claimed in claim 1, said receptacle defining a complex profile, wherein said profile is cooperatively configured with multiple standard beverage cans having differing radii, so as to present a contact surface area of engagement with at least five percent of the outside surface area of each can, when either can is placed within the receptacle. 16. The dock as claimed in claim 1, wherein said at least one body further defines an array of cups configured to form ice cubes at an accelerated rate, when the dock is placed within the air, so as to be caused to achieve the temperature, and a liquid is placed therein after the dock has achieved the temperature. 17. A rapid cooling assembly adapted for use within chilled air encased within a compartment, and for accelerating the cooling of a standard beverage can and the formation of ice cubes, wherein the air presents an average temperature, the can presents an outside can surface area, and the can and the air cooperatively produce a first heat transfer rate from the can and to the air when the can Is placed within the air, said assembly comprising; at least one body having a first surface, said first surface defining a receptacle, said receptacle being cooperatively configured with the can to present a contact surface area of engagement with at least five percent of the outside can surface area, when the can is placed within the receptacle, said at least one body presenting a mass, density, and thermal conductivity operable to cause heat transfer from the can and to said at least one body at a second rate greater than the first heat transfer rate when the can is placed within the receptacle and said at least one body is at the average temperature; andan ice tray presenting a composition, and defining an outside tray surface area, and a plurality of cups, each cup being operable to hold a quantity of liquid,said receptacle being cooperatively configured with the tray to present a contact surface area of engagement with at least five percent of the outside tray surface area when the tray is placed within the receptacle,said at least one body presenting a mass, density, and thermal conductivity operable to cause heat transfer from the tray and to said at least one body at a second rate greater than the first heat transfer rate when the can is placed within the receptacle and said at least one body is at the average temperature. 18. The assembly as claimed in claim 17, said receptacle defining a complex profile, wherein said profile is cooperatively configured with multiple standard beverage cans having differing radii, so as to present a contact surface area of engagement with at least five percent of the outside can surface area of each can when placed within the receptacle.
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