Improvements to a refrigerator with carbonated drink spout that provides a drink at the exterior of the door of the refrigerator. The improvement allows people with different tastes to select a flavor syrup cartridge, insert the flavor syrup in a external port in the door of the refrigerator and dispense the beverage using fluids that are chilled by the refrigerator. It frees the interior space of the refrigerator that is used to store cold flavored water and carbonated beverages. The refrigerator includes an internal CO2 tank and separate reservoirs of refrigerated flat and refrigerated carbonated water. The delivery system is flushed with each use to eliminate cross contamination of flavors or syrups.

A beverage dispenser uses-high ratio concentrates to mix on-demand beverages. The high-ratio concentrate is pre-mixed with an alkaline water to allow for improved blending performance in the final beverage. The beverage recipe may be customized by the user to suit personal tastes. Aspects of the beverage dispenser also may include the ability to dispense room temperature, chilled, heated, sparkling, or highly alkaline beverages. Operation of a user interface to receive a beverage order includes the ability to display and employ user interfaces present on both a display on the beverage dispenser and an application on a mobile device. In some aspects, both user interfaces may be used simultaneously to receive user input. Methods of dispensing a beverage using the beverage dispensing systems are also discussed.

A device for storing and circulating drinking water with vortex flow includes a base, a tank and an actuator housed in the base and configured to circulate the drinking water stored in the tank with vortex flow. The base includes an inlet port through which the drinking water is received and an outlet port through which the drinking water is dispensed. The tank is mounted on the base with a sealed engagement and is configured to store the drinking water. The tank has spherical or egg shape and includes an air inlet on an upper portion of the tank through which air can flow in and out of the tank.

Disclosed herein are beverage dispensing apparatuses for selectable gas-infused beverage dispensing. The apparatus may have a faucet assembly, a beverage storage unit, a gas storage unit, a liquid/gas infusion unit, and an infusion valve. The faucet assembly may have a housing, a nozzle, a supply valve, and a dispensing valve, configured to control a flow of beverage through the faucet assembly. The beverage dispensing apparatus may use the infusion valve to selectively infuse a selected level of gas within a dispensed beverage.

A dispenser head for in-line mixing and dispensing of beverages, which may be carbonated or nitrogenated. The dispenser head comprising a pump, a dilution mechanism, an additive mechanism, and outlet nozzle and optionally a regulation system. In use, the pump can pump concentrate liquid for the liquid product from a concentrate source to the dilution mechanism; the dilution mechanism can receive diluent liquid suitable for the liquid product from a diluent source, operable to mix the diluent liquid and the concentrate liquid and provide diluted concentrate liquid; and the additive mechanism can receive additive fluid for the liquid product from an additive source, to combine the diluted concentrate liquid and the additive fluid. The regulation system comprises a pump regulator means for regulating the quantity of concentrate liquid pumped into the dilution mechanism within the dispense period; a diluent quantity regulator means for regulating the flow of diluent liquid into the dilution mechanism; and an additive quantity regulator means for regulating the flow of additive fluid into the additive mechanism. Preferably, the dispenser head is a unitary device, which may be supplied attached to a vessel containing the concentrate.

A water ejecting apparatus includes a case and a water ejection unit connected to one side of the case. The water ejection unit includes a fixed cover, a lifting cover, a lifting motor, a water ejection nozzle, a touch bar, a detection sensor, and a controller. The fixed cover is connected to the case. The lifting cover is movably received in the fixed cover and coupled to the lifting motor. The water ejection nozzle is installed at a lower end of the lifting cover and configured to eject water. The touch bar is at least partially received in the lifting cover and moves when in contact with a container placed below the water ejection nozzle. The detection sensor detects movement of the touch bar. The controller changes operation of the lifting motor when the detection sensor detects movement of the touch bar.

The present invention relates to a beverage making machine comprising a first beverage making cartridge comprising at least one of a gas source portion, the gas source portion contains a solid gas source that through sublimation emits a gas, and a gas storage tank arranged to store the gas emitted from the solid gas source. The beverage making machine further comprising a second beverage making cartridge comprising at least one of a micro ingredient, a beverage diluent receptacle for receiving a beverage diluent liquid, a dissolver dissolves portion of the gas, from the gas storage tank, into the beverage diluent liquid, and a dispenser selectively dispenses a predefined ratio of at least one of the micro ingredient and the beverage diluent liquid, to form a beverage. Exemplary embodiments include a computer control arranged to receive a beverage selection from a consumer and control the beverage making machine to form beverages.

A drink station is provided with an alkaline filter cartridge in fluid communication with an ambient temperature water line provide alkaline water, and with a chilled water mixed with the alkaline water at a spigot to provide chilled alkaline water. A hot water heating element is located below the spigot so hot water flows upward for dispensing from the spigot, with a vent line between the heating element and spigot helping hot water to flow from the spigot to the heating element. A refrigeration system and a carbonation system is also provided. The refrigeration system uses the ice-bank technology. A submersible agitator pump improves heat exchanged between ice-bank and water by forced convection. The agitator pump operating based on the temperature of the drinking water. A figure eight evaporator coil can provide two cylindrical ice banks and two chilled water coils to increase the chilled water capacity.

A mixing valve is described for a dispensing device for dispensing a cooled beverage mixed with a gas, comprising: a first inlet which can be fluidically connected to a first source of gas and can be supplied with the gas; a second inlet which can be connected to a second source of the beverage without gas and can be supplied with the beverage not mixed with the gas; an outlet which can be connected to a first dispensing mouth for dispensing the beverage mixed with the gas; the dispensing mouth is available in a closed or open configuration to prevent or allow dispensing of the beverage mixed with said gas; a chamber interposed between the first and the second inlet on one side and the outlet on the other side and adapted to allow mixing of the gas and non-mixed beverage, thus forming the beverage mixed with the gas; and regulation means, configured to allow, when the first dispensing mouth is arranged in the open configuration, the passage, respectively, of a first flow value of gas between the first inlet and the outlet and a second flow value of non-mixed beverage between the second inlet and the outlet.

A gas liquid absorption device (GLAD), featuring a gas inlet manifold, a liquid inlet manifold and a gas/liquid mixing foamer. The gas inlet manifold has a gas inlet configured to receive and provide an inlet gas, and also has a gas foamer cavity formed therein and coupled fluidically to the gas inlet to receive the inlet gas. The liquid inlet manifold has a liquid inlet configured to receive and provide a non-infused liquid, and also has a liquid foamer cavity formed therein and coupled fluidically to the liquid inlet to receive the non-infused liquid. The gas/liquid mixing foamer is configured between the gas inlet manifold and the liquid inlet manifold and arranged in the gas foamer cavity and the liquid foamer cavity. The gas/liquid mixing foamer has a gas foamer wall configured to form a gas receiving foamer chamber that is fluidically coupled to the gas foamer cavity. The gas foamer wall has gas provisioning holes formed therein to provide dispersed inlet gas from the gas receiving foamer chamber. The gas/liquid mixing foamer has a liquid foamer wall configured to form a liquid receiving foamer chamber that is fluidically coupled to the liquid foamer cavity. The liquid foamer wall having liquid provisioning holes formed therein to provide dispersed non-infused liquid from the liquid receiving foamer chamber. The mixing chamber is configured to receive the dispersed inlet gas and the dispersed non-infused liquid, infuse the dispersed inlet gas and the dispersed non-infused liquid, and provide a foamed gas/liquid mixture from the mixing chamber.