The device includes a container (10) having a top (12) and a bottom (14). A receptacle (15) is formed in the container and joined to an orifice (22) at the bottom (14). A cooling medium (26) is contained within the receptacle and able to retain a cooling environment to cool the beverage. In one embodiment, a beverage container has an opening (72) that permits the emptying of the beverage from the container and a coolant capsule (73) within said container. The cooling capsule (73) contains a cooling medium and the capsule is dimensioned such that the capsule is larger than the opening (72) but has surface characteristics (77,78) which permit the beverage within the container to bypass the capsule (73) and to exit the opening.

An environmental control assembly for controlling at least one environmental condition of one or more substances, the one or more substances being uncontained or contained within a substance container, the assembly comprising a first enclosure comprising a thermal insulator configured to provide a thermal shield to the substance, a second enclosure comprising at least one deformable environmental control material configured to regulate at least one environmental condition of the substance, wherein the second enclosure at least partially physically contacts with at least one of the substance and the substance container, and a housing at least partially comprising the first enclosure and the second enclosure.

An insulated cooler with a submersible internal circulating pump is provided. The insulated cooler includes a base, a plurality of sidewalls extending upwardly therefrom, and an open upper end defining an interior volume. The insulated cooler further includes a lid that is removably secured over the open upper end, wherein the lid includes multiple recessed cup holders with sidewalls that extend downwardly into the interior volume of the insulated cooler. The insulated cooler includes a submersible internal circulating pump operably connected to a system of copper tubing that winds around the sidewall of the recessed cup holders. When activated, the submersible internal circulating pump transports melted ice water through the tubing, which cools the sidewall of the recessed cup holders. In this way, the insulated cooler can cool objects within the interior volume and can cool beverages that are supported within the exterior cup holders.

A refrigerator includes a cooling/heating chamber capable of cooling and heating foods. The cooling/heating chamber is divided into a heating zone that is a space where foods to be heated are placed, and a non-heating zone that is a space continuous with the heating zone where foods not to be heated are placed. The refrigerator further includes an oscillation electrode and a counter electrode that are arranged so as to face each other with the heating zone in between, and an oscillating unit that applies an AC voltage to between the oscillation electrode and the counter electrode.

A beverage-making apparatus includes a fermentation tank assembly including a fermentation tank having an opening formed therein and a fermentation tank cover configured to open and close the opening. The beverage-making apparatus also includes a refrigeration cycle apparatus including a compressor, a condenser, an expansion device, and an evaporator. The refrigeration cycle apparatus is configured to circulate a refrigerant therethrough and to control a temperature of the fermentation tank as the evaporator is disposed at the fermentation tank. The beverage-making apparatus further includes a heat insulating wall surrounding both the fermentation tank and the evaporator.

Portage storage containers including controlled evaporative cooling systems are described herein. In some embodiments, a portable container including an integral controlled evaporative cooling system includes: a storage region, an evaporative region adjacent to the storage region, a desiccant region adjacent to the outside of the container, and an insulation region positioned between the evaporative region and the desiccant region. A vapor conduit with an attached vapor control unit has a first end within the evaporative region and a second end within the desiccant region. In some embodiments, the controlled evaporative cooling systems are positioned in a radial configuration within the portable container.

A system may include a beverage compartment with a beverage positioned therein, a wetted material disposed about the beverage, at least one sorption cartridge, and a vacuum pump. The sorption cartridge may be in communication with the beverage compartment, and the vacuum pump may be in communication with the sorption cartridge to create a vacuum in the sorption cartridge and the beverage compartment, causing water to evaporate from the wetted material and be captured by the sorption cartridge, thereby lowering the temperature of the wetted material and in turn cooling the beverage. In some instances, the sorption cartridge may be detached from the vacuum pump and the beverage compartment to discharge the captured water therein by way of solar energy. In other instances, the sorption cartridge may be in communication with a heater assembly to blow heated air through the sorption cartridge to discharge the captured water therein.

A system may include a beverage compartment with a beverage positioned therein, a wetted material disposed about the beverage, at least one sorption cartridge, and a vacuum pump. The sorption cartridge may be in communication with the beverage compartment, and the vacuum pump may be in communication with the sorption cartridge to create a vacuum in the sorption cartridge and the beverage compartment, causing water to evaporate from the wetted material and be captured by the sorption cartridge, thereby lowering the temperature of the wetted material and in turn cooling the beverage. In some instances, the sorption cartridge may be detached from the vacuum pump and the beverage compartment to discharge the captured water therein by way of solar energy. In other instances, the sorption cartridge may be in communication with a heater assembly to blow heated air through the sorption cartridge to discharge the captured water therein.

The present invention provides a highly reliable and safe heating device that can uniformly heat an object to be heated and provides a refrigerator having a storage space in which frozen products as storage products can be easily thawed to a high-quality state. A heating device of the present invention includes an oscillation electrode disposed on one hand of the heating space and having an electrode surface on which an electric field concentration region is formed, a counter electrode disposed on the other hand of the heating space and having an electrode surface that faces the electrode surface of the oscillation electrode, and a high-frequency electric field forming unit for forming a high-frequency electric field applied to between the oscillation electrode and the counter electrode.

A chiller for cooling a beverage includes a reservoir configured to hold a heat exchange fluid and an evaporator coil arranged within the reservoir. The evaporator coil includes a plurality of windings configured to circulate a coolant, and projections extending from an exterior surface of one or more of the plurality of windings. The chiller further includes a chiller coil arranged in the reservoir, wherein the beverage is configured to flow through the chiller coil. When the coolant is circulated through the plurality of windings of the evaporator coil, a bank of frozen heat exchange fluid forms on the windings and on the projections.