An insulated beverage sleeve assembly includes a cylinder that insertably receives a beverage container. A first flap is movably attached to the cylinder to close the cylinder. A second flap is movably attached to the cylinder to close the cylinder. A top insulator is releasably matable to the first flap to engage the beverage container. A bottom insulator is releasably matable to the second flap to engage the beverage container. Each of the top insulator and the bottom insulator are comprised of a thermally insulating material. A cooling sleeve is insertable into the cylinder to surround the beverage container. Moreover, the cooling sleeve is comprised of a refrigeratable material such that the cooling sleeve can be refrigerated thereby facilitating the cooling sleeve to cool the beverage container.

A beverage dispensing machine (e.g., coffee maker) has a cooling unit. The cooling unit includes a thermal mass. The cooling unit is operable to freeze at least a portion of the thermal mass to provide a cold storage reservoir. The cooling unit also includes a passageway within which a brewed beverage flows, the passageway being in thermal communication with the thermal mass that cools the brewed beverage as it flows within the passageway to chill the brewed beverage before it is dispensed.

The application discloses an insulating device or “cooler” for a canned or bottled drink with an attached handle that itself accommodates a cylindrical, semi-cylindrical, or rectilinear object. A cigarette lighter or the like may be stored in the handle.

A food preparation table includes a housing at least in part defining multiple food pan receiving locations and a cooling air flow path internal of the housing below the food pan receiving locations. A first food pan is positioned within a first one of the food pan receiving locations such that side walls and a bottom wall of the first food pan are within the cooling air flow path, a first one of the side walls of the first food pan includes a plurality of openings therein to permit some cooling air to enter the first food pan and flow in contact with food items therein.

A heating and cooling device includes a heating and cooling module, which is positionable in a cupholder of a vehicle. A power and signal cable is operationally engaged to and extends from the heating and cooling module. A controller is engaged to the power and signal cable distal from the heating and cooling module. The controller selectively signals the heating and cooling module to execute at least one heating mode and at least one cooling mode. The heating and cooling module thus can selectively heat or cool a beverage that is positioned in a cup within the cupholder. A power cord is engaged to and extends from the controller. A plug is engaged to the power cord distal from the controller. The plug is insertable into a power port of the vehicle to power the heating and cooling module.

Various embodiments may relate to a radiant cooler. The radiant cooler may include a chamber. The radiant cooler may also include a vacuum pump connected to the chamber. The radiant cooler may further include an infrared absorber arranged within the chamber. A wall of the chamber may be configured to allow at least a portion of infrared light to pass through. The vacuum pump may be configured to generate a vacuum in the chamber. The infrared absorber may include a fluid, i.e. a liquid, configured to evaporate into the vacuum upon receiving thermal energy from at least the portion of infrared light.

Various embodiments may relate to a radiant cooler. The radiant cooler may include a chamber. The radiant cooler may also include a vacuum pump connected to the chamber. The radiant cooler may further include an infrared absorber arranged within the chamber. A wall of the chamber may be configured to allow at least a portion of infrared light to pass through. The vacuum pump may be configured to generate a vacuum in the chamber. The infrared absorber may include a fluid, i.e. a liquid, configured to evaporate into the vacuum upon receiving thermal energy from at least the portion of infrared light.

A solid state cooler device is provided that includes a substrate, a first and second conductive pad disposed on the substrate, a first and second superconductor pad each having a side with a plurality of conductive pad contact interfaces spaced apart from one another and being in contact with a surface of respective first and second conductive pads, and a first and second insulating layer disposed between respective first and second superconductor pads, and respective ends of a normal metal layer. A bias voltage is applied between one of a first conductive pad or first superconductor pad and one of the second conductive pad or the second superconductor pad to remove hot electrons from the normal metal layer, and the contact area of the plurality of first and second conductive pad contact interfaces inhibits the transfer of heat back to the first and second superconductor pads.

A solid state cooler device is provided that includes a substrate, a first and second conductive pad disposed on the substrate, a first and second superconductor pad each having a side with a plurality of conductive pad contact interfaces spaced apart from one another and being in contact with a surface of respective first and second conductive pads, and a first and second insulating layer disposed between respective first and second superconductor pads, and respective ends of a normal metal layer. A bias voltage is applied between one of a first conductive pad or first superconductor pad and one of the second conductive pad or the second superconductor pad to remove hot electrons from the normal metal layer, and the contact area of the plurality of first and second conductive pad contact interfaces inhibits the transfer of heat back to the first and second superconductor pads.

A self-cooling container for cooling a liquid includes a first portion with a first frangible seal that extends across and seals an evaporator unit containing a refrigerant and a second portion with a second frangible seal that extends across and seals a desiccant chamber containing a desiccant. The first portion rotates axially relative to the second portion. An actuator assembly is between the first portion and the second portion and includes: a cutter assembly, which is coupled to the first portion of the self-cooling container and includes a cutter coupled to a rotatable axle and a pinion gear coupled to the rotatable axle, and a drive gear assembly coupled to the second portion of the self-cooling container and including a ring gear supported by a housing. The pinion gear on the cutter assembly is mated to the ring gear of the drive gear assembly.