A door panel for a refrigerating appliance includes an inner liner. An outer wrapper is attached to the inner liner and defines an insulating structure with an insulating cavity disposed therein. An insulating material is defined within the insulating cavity. A dispenser structure is defined within a central portion of the inner liner and the outer wrapper. The dispenser structure defines an insulated dispenser portion therein. A dispenser conduit extends from an interior area disposed above the dispenser structure to an external dispensing cavity and passing through the insulated dispenser portion.

The present invention provides a refrigerator and a beverage supply device thereof. The beverage supply device comprises: a supporting seat, an adapting seat, a liquid outlet mechanism, and a blocking member for fitting with a mouth of a beverage container, the blocking member having a channel fitted with the liquid outlet mechanism, the blocking member being disposed on the adapting seat and rotating synchronously with the adapting seat when the blocking member is located at an initially-assembled position, the beverage container is fitted to the blocking member in a state where the mouth of the beverage container is higher than a liquid level of the beverage; when the blocking member is located at a fully-assembled position, the beverage container is vertically inverted on the blocking member.

A refrigerator includes a main body having a storage compartment, a door to open or close the storage compartment, and a dispenser provided on the door and configured to supply water to the outside of the main body, wherein the door includes, a door plate, and a door cap coupled to a lower end portion of the door plate and having a water collecting part to collect residual water of the dispenser.

A reusable pump dispenser may simultaneously dispense and cool a product to a user. The product may be dispensed or dosed in predetermined and/or amounts desired by a user. The product may be cooled from an ambient temperature to a product application temperature. A cooling circuit subassembly may control the temperature, viscosity, and additional properties of the product, thereby providing a maximum benefit of the product when applied to the user. The reusable pump dispenser may eliminate microbes from the product and may provide a physical structure that may be held in a user's hand. The reusable pump dispenser may provide a reusable housing that may be easily replaced, refilled, and reused.

An ice bath comprising a container, a refrigeration coil for causing liquid in the container to turn to ice, a pipe for carrying liquid to be cooled by the ice bath for dispense and a plurality of conductive probes for measuring ice thickness, wherein the conductive probes are provided between at least part of the refrigeration coil and the pipe for carrying liquid to be dispensed such that a first one of the conductive probes is provided closer to the refrigeration coil at least two other conductive probes, and thereby the at least two other conductive probes are provided closer to the piping than the first conductive probe, and wherein the second and third probes are equidistant from the refrigeration coil, the ice bath further comprising means for measuring the conductance between the first probe and the second probe, the first probe and the third probe, and the second probe and the third probe.

Provided are a refrigerator and an energy-saving control method and apparatus therefor. The refrigerator includes an ice maker. The ice maker includes an ice discharge electric motor (1), an ice storage bin (2) and an ice storage bin position switch (3). The method includes: detecting and determining that the ice storage bin (2) is in a full ice state; controlling the ice maker so that same stops making ice, and acquiring the state of at least one of the ice discharge electric motor (1) and the ice storage bin position switch (3); and according to the state of at least one of the ice discharge electric motor (1) and the ice storage bin position switch (3), determining that the ice maker needs to do heating and ice detection actions.

Methods and systems are provided for mixing and heat exchange of fluids. In one example, a fluid mixing and heat exchange device includes a hot water tank, a mixing chamber spaced away from the hot water tank and fluidly coupled to a first liquid reservoir, a first chilling module fluidly coupled to the mixing chamber, a coolant tank fluidly coupled to the first chilling module, a radiator fluidly coupled to the coolant tank, and a dispensing manifold fluidly coupled to the mixing chamber and adapted to dispense a mixed and chilled fluid mixture to a plurality of fluid vessels.

A door panel for a refrigerating appliance includes an inner liner. An outer wrapper is attached to the inner liner and defines an insulating structure with an insulating cavity disposed therein. An insulating material is defined within the insulating cavity. A dispenser structure is defined within a central portion of the inner liner and the outer wrapper. The dispenser structure defines an insulated dispenser portion therein. A dispenser conduit extends from an interior area disposed above the dispenser structure to an external dispensing cavity and passing through the insulated dispenser portion.

A beverage storage container is described. The beverage storage container includes a removable core containing a viscous temperature sensitive fluid and a containing vessel base configured to hold the temperature sensitive core. The beverage storage container also includes a containing vessel body configured to be in thermal connection with the removable core; and a thermoplastic insulator configured to prevent rapid transfer of temperature between the removable core and the containing vessel body.

A method of fabricating a refrigerator cabinet or door includes forming a wrapper and an inner liner. The method further includes forming a vacuum insulated core comprising a permeable core material that is disposed inside an impermeable envelope. A sheet of prefabricated compressible foam material is positioned between the vacuum insulated core between the inner door liner and/or the door wrapper. The prefabricated compressible foam material may be cut from a sheet of foam having substantially uniform thickness prior to fabrication of the refrigerator door. The foam compresses to accommodate differences in spacing between the vacuum insulated core and the door wrapper and/or the door liner.