The present invention relates to an improved adaptable cooling sleeve to maintain or lower the temperature of a beverage. Embodiments of the present invention provide an adaptable cooling sleeve device, hereinafter referred to as the sleeve, having a securing mechanism, a cooling pack that stabilizes the temperature of the beverage container, and an insulating exterior layer. The securing mechanism allows the device to be adjusted to allow the sleeve to accommodate beverage containers of a variety of shapes and sizes. The cooling pack comprises a coolant, such as a liquid or gel, that acts as a temperature stabilizing heat sink for the beverage contents for a period of time. The insulating exterior layer thermally isolates the contents of the beverage and the cooling pack from the atmosphere.

The present invention relates to a flexible, collapsible and insulating container cover for enclosing a container that maintains the temperature of the contents of the container. The cover has a closure mechanism positioned near its top opening, so that the same can be opened for inserting the container. At least one pocket is also positioned on the cover, either on a front surface or near a bottom surface of the cover, for receiving and storing a temperature-conforming pack for maintaining a temperature of the contents of the container.

A system for manipulating heat transfer includes a thermal sleeve, a vessel and a lid. The thermal sleeve includes a first material and a second material. The vessel includes an outer wall disposed about an inner wall, the inner wall defining a reservoir configured to contain a liquid and the inner wall and outer wall defining a gap therebetween. The lid is configured to open to facilitate adding of the liquid to the reservoir. The thermal sleeve is configured to be positioned within the gap.

A cooling drink holder assembly includes a sleeve that has a compartment is integrated inside of the sleeve. The compartment is filled with a cooling gel to cool the beverage container when the beverage container is inserted into said sleeve. A first ring is coupled to the sleeve and a plurality of couplers is each coupled to the first ring. A second ring is included and a plurality of engagements is integrated into the second ring. Each of the couplers on the first ring releasably engages a respective one of the engagements for suspending the sleeve on an arm rest of a chair. In this way the sleeve can store the beverage container when the beverage container is extended through the arm rest of the chair.

Disclosed are a cold-water generating tank for generating cold water by using the ice thermal storage method and a water cooler equipped with same. The disclosed cold-water generating tank may comprise: a tank body which houses, on the inside thereof, an ice storage liquid cooled by means of a cooling unit; a cooling tube provided on the inside of the tank body in order to cool the ice storage liquid housed inside the tank body; and a cold-water generating unit which has a heat exchange tube forming a flow pathway where inflowing water becomes cold water through heat exchange with the ice storage liquid, and has an extension member positioned on the outer circumferential surface of the heat exchange tube in order to widen the area of contact with the ice storage liquid.

A mechanical apparatus comprised of a plurality of pods in the form of a cylindrical sleeve, containing liquid, to be frozen for the purpose of dynamically transfer/impart its charged thermal energy to a directly contacted object placed within. The pods are joined to each other by elastic bands allowing it to instantly expanse and grip varying size beverage containers. Furthermore, the plurality of pods and a beverage container are disposed in an insulated holder; a sealable cap is then inserted to seal off and insulate the discharging of thermal energy therein from ambient conditions. A beverage in the form of can or bottle may be placed in the apparatus to achieve desired chill temperature for an extended length of time in high ambient temperature conditions.

A beverage container includes a base, a stem, and a bowl. The base has a base lateral dimension parallel to the horizontal supporting plane. The stem extends upwardly from a stem lower end coupled to the base to a stem upper end. The stem has a heat pipe extending between the stem lower end and the stem upper end. The stem has a stem lateral dimension smaller than the base lateral dimension. The bowl is coupled to the stem upper end and extends upwardly of the stem. The bowl defines a liquid chamber having an upper opening. Other beverage containers, systems, methods, and heat transfer pads are also disclosed.

The thermal sleeves for bottle includes a bottle that includes a sealable closure at a top opening. The exterior of the bottle enables at least one thermal sleeve to be affixed there against in order to increase the overall insulative quality of the bottle. The at least one thermal sleeve may include at least one layer of a freezer gel material, which when placed into a freezer becomes hardened. The at least one thermal sleeve also includes a storage compartment that is accessible via a top opening. The top opening of the at least one thermal sleeve includes a sealing member to selectively close and unseal the top opening. The storage compartment is ideally used to store a powder that may be mixed into a fluid provided in the bottle.

A vessel for chilling wine with ice or ice-water mixture has an inner support chamber for standing up wine bottle and separating them from liquid water to avoid over chilling. The inner support as a plurality of perforations in an upper portion of the vessel to facilitate heat exchange. As ice outside the support melts, the water formed will remain below the perforations.

An insulated container for storing or shipping bottles includes a body and a lid. The body has a shell and an insert portion formed from an insulating material. The lid also has a shell and an insert portion formed from the insulating which meets the insert portion of the body to form cavities. The cavities include a temperature control pack cavity and four or more separate bottle storage cavities distributed around the temperature control pack cavity. Each of the bottle storage cavities is configured for receiving a bottle from among three or more different bottle types. Each of the bottle types has a different shape and/or size than each of the other bottle types. Each of the bottle storage cavities includes at least three bottle stop features on one or more internal surfaces. Each bottle stop feature is associated with a different one of the three or more bottle types.