A beverage dispenser has a housing in which a first liquid inlet is connectable to a base liquid source. The housing also contains a second liquid inlet connectable to a base liquid source or to a pressurized gas source and a pair of jet mixers. First and second liquid lines connect the respective first and second liquid inlets and jet mixers. A first ingredient container contains a first beverage ingredient, the pod or capsule provided in a first ingredient container receiving means, and a second ingredient container containing a second beverage ingredient, the ingredient container provided in a second ingredient container receiving means. The first and second ingredient containers are configured such that upon providing a liquid stream in the respective liquid lines, the beverage ingredient is discharged from the ingredient container into the liquid stream. A beverage outlet is in liquid communication with the jet mixer.

A beverage dispensing device has a housing with a beverage unit with a liquid inlet and a beverage outlet. The beverage unit has a receiving means for receiving at least two ingredient containers containing a unit dose of an ingredient of the beverage to be dispensed. The beverage unit also has a liquid line in fluid communication with a base liquid source, with the contents of the ingredient containers, when correctly installed in the device, and with the beverage outlet. The liquid line is split into two side lines at a point A, downstream the liquid inlet. Both side lines join in fluid communication at a point B, downstream point A and upstream the beverage outlet, at least one of the ingredient containers in liquid communication with the liquid line at a point M1 downstream point A and upstream point B.

A beverage dispensing assembly for preparing and dispensing a beverage has a source of pressurized base liquid containing dissolved CO.sub.2, N.sub.2 or N.sub.2O and a gas pressure of at least 0.5 bar overpressure at 2° C. A beverage unit with a liquid flow path has a liquid inlet at one end in fluid communication with the base liquid in the base liquid source and a beverage outlet at an opposite end. An ingredient container receiving means has an ingredient container installed so the contents are in fluid communication with the liquid flow path for mixing the contents with a base liquid in the liquid flow path. A gas pressure regulation unit has a pressure chamber in the liquid flow path downstream of the communication between the liquid flow path and the ingredient container contents. A gas ingredient inlet is in fluid communication with the pressure chamber.

A mixed beverage production appliance has a first container which is configured for receiving a first fluid having a first freezing point and is able to be added to a mixed beverage and a second container which is separate therefrom and which is configured for receiving a second fluid having a second freezing point which is different from the first freezing point and which is able to be added to a mixed beverage. The two containers are connected into a refrigerating circuit of the mixed beverage production appliance which is configured such that the two containers are able to be subjected to different temperatures independently of one another.

A system and method for dispensing fluids is introduced. A preferred embodiment comprises a sealed tank, a bag containing fluid inside the sealed tank, an outlet for dispensing the liquid in the bag, and a pressure generating device to create pressure in the sealed tank.

Disclosed is a beverage dispensing system for dispensing a non-mixed fluid along with a post-mix fluid. The post-mix fluid is formed by mixing a base beverage with at least one beverage additive. For example, the beverage dispensing system may dispense a post-mix fluid (e.g. cola) and a non-mixed fluid (e.g. spirits) separately. In some embodiments, the post-mix fluid may be dispensed simultaneously with the non-mixed fluid from separate fluid outlet ports. In other embodiments, the post-mix fluid may be dispensed from a first fluid outlet port and, subsequently, the non-mixed fluid may be dispensed from a second fluid outlet port.

A decompression mechanism may include a decompression case having an inlet that receives a beverage and an outlet that discharges the beverage; a decompression inner member including an inner body positioned inside of the decompression case and a guide formed in a spiral shape on an outer circumference of the inner body and in contact with an inner face of the decompression case; and a decompression channel defined between the decompression case and the decompression inner member. The decompression channel may have an input opening in communication with the inlet and an output opening in communication with the outlet, and a cross-sectional area of the decompression channel may increase as the decompression channel extends from the input opening to the output opening.

Vertical beverage dispensers including a vertical dispensing manifold for dispensing a beverage. The vertical dispensing manifold may include an input port coupled to one end of a vertical shaft and a dispensing nozzle coupled to the other end of the vertical shaft. The vertical shaft may include a hollow interior and a plurality of orifices for introducing ingredients into the hollow interior formed in the sidewall of the vertical shaft. The vertical shaft may define a vertical flow path for the flow of a base liquid from the input port, through the vertical shaft to combine with one or more ingredients, and to the dispensing nozzle. The flow of base liquid and ingredients within the vertical shaft may be uniform.

An ice dispensing system is provided. The system includes multiple sidewalls forming an ice bin cavity configured to store ice. The system further includes an auger drive assembly. The auger drive assembly includes a drive assembly that is coupled to one of the multiple sidewalls and has a motor configured to rotate a drive gear. The auger drive assembly further includes an auger assembly positioned within the ice bin cavity. The auger assembly includes a helical auger coupled to an auger gear. The drive gear is configured to mate with the auger gear to drive rotation of the helical auger and cause ice to be dispensed through an ice chute. The drive assembly is additionally configured to move relative to the auger assembly between a closed position and an opened position. The opened position permits removal of the auger assembly from the ice bin cavity.

The present application provides a beverage dispensing system using a sweetener. The beverage dispensing system may include a sweetener source with the sweetener therein, one or more rotating or stationary components positioned about a flow of the sweetener, and a component wash system positioned about the one or more rotating or stationary components to wash off the sweetener thereon.