Dispensing sequences for beverage mixture dispensing systems are disclosed. A disclosed method for operating a beverage mixture dispensing system includes flowing a first solvent from a first reservoir to a mixing area of the beverage mixture dispensing system, dispensing concentrated ingredients into the mixing area to combine the first solvent from the first reservoir with the concentrated ingredients to form an intermediate mixture, flowing the intermediate mixture to a mixing chamber of the beverage mixture dispensing system, flowing a sweetening liquid from a second reservoir to the mixing chamber, without flowing the sweetening liquid through the mixing area, to combine the sweetening liquid from the second reservoir with the intermediate mixture to form a beverage, and dispensing the beverage from the mixing chamber. A disclosed device is configured to execute this method. A disclosed computer-readable medium includes instructions for a device to execute this method.

The apparatus includes a reservoir (2), a liquid source (1), a carbon dioxide source (12), a non-return valve (8), a carbonating vessel (7) to receive liquid from the reservoir (2) via the non-return valve (8), a gas inlet (15) to receive carbon dioxide from the carbon dioxide source (12), and a dip tube (16) to withdraw carbonated liquid from the carbonating vessel. A pressure relief valve (20) vents gas from the carbonating vessel (7), and a dispense valve (18) controls the supply of carbonated liquid from the dip tube (16) to a dispense outlet (17). A charge control valve (14) controls the supply of carbon dioxide to the carbonating vessel (7). The apparatus has the following modes of operation-charge: the dispense valve (18) is held closed while the charge control valve (14) is opened to admit a charge of carbon dioxide into the carbonating vessel (7); dispense/refill: the dispense valve (18) is opened to dispense carbonated liquid while liquid flows into the carbonating vessel from the reservoir (2) via the non-return valve (8). The carbonated beverage can

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A backblock includes a body with a cavity connected to an inlet and an outlet. A spindle is positioned with a first end within the cavity and a second end with a tab exterior of the body. A latching plate is configured for translative movement relative to the body. The latching plate includes a keyhole with a bore and a channel. The bore is dimensioned to receive the spindle and the channel is dimensioned to receive the tab. The latching plate has a first latch position proximate to the body and a second latch position spaced apart from the body. When the tab is in alignment with the channel, the latching plate can translate to the second latch position about the tab. When the tab is out of alignment with the channel, the tab retains the latching plate in the first latch position.

The present application thus provides a beverage dispensing system for combining a micro-ingredient and a diluent. The beverage dispensing system may include a nozzle and a remote micro-ingredient storage system positioned at a distance from the nozzle. The remote micro-ingredient storage system may include a stirring reservoir in communication with the nozzle to agitate the micro-ingredient therein.

A beverage system that produces a fermented beverage from two or more liquid streams, includes a first source including an ultra-high gravity beverage at a pressure of 82.7 kPa to 1034.2 kPa; a second source including a carbonated and/or nitrogenated water at a pressure of 82.7 kPa to 1034.2 kPa and and a temperature of 0° to 8°; a mixing point that allows mixing of the ultra high gravity beverage to blend with the carbonated and/or nitrogenated water to produce a fermented beverage; and a fluid line fluidly coupled to the mixing point and configured to allow the fermented beverage to flow to a dispensing tap. The fluid line has a length of 0.3048 m to 45.72 m and an inner diameter of 3.2 mm to 15.9 mm for at least a portion of the line.

Beverage dispensers are disclosed. A beverage dispenser may include a carbonation pump, pressure tank, and a pressure switch configured to active the pressure pump when a pressure in the pressure tank falls below a threshold pressure. The pressure switch may cause the carbonation pump to shut off when the pressure in the pressure tank exceeds an upper threshold pressure. The beverage dispenser may be convertible from a carbonated beverage dispenser to a non-carbonated beverage dispenser.

A drink making device including a hood, a base configured to support at least four bottles, a tower connecting the base and the hood; and a dispenser for dispensing a beverage. The hood includes at least four attachment connectors. Liquid from the bottles is selectively pumped through the connectors through the dispenser to dispense a beverage.

A carbonated water dispenser comprises a carbonator with a water inlet and a carbonated water outlet. A backflow preventer module is fluidically coupled to the water inlet and comprises a check valve and a thermal mass flow meter. The thermal mass flow meter is configured to communicate a first signal based on a measured amount of heat transferred from a heater to a temperature sensor by a flow of a fluid through the backflow preventer module. A shut-off valve is fluidically coupled between the carbonated water outlet and a nozzle. The shut-off valve is configured to allow or prevent fluid flow from the carbonated water outlet to the nozzle base on a control signal. A controller is configured to detect a backflow condition based on the first signal and generate the control signal to configure the shut-off valve to prevent dispensing carbonated water upon detection of the backflow condition.

A beverage dispensing machine for dispensing a mixed beverage has a first inlet configured to receive a concentrate; a second inlet configured to receive a base fluid; a gas inlet configured to receive a gas; a gas injection device configured to pulsate the gas into the concentrate such that the gas agitates the concentrate and is injected into the concentrate to form a gas-injected concentrate; and a dispensing valve configured to dispense the base fluid and the gas-injected concentrate.

The present invention relates to a device for preparing and dispensing reconstituted beer, said device comprising: a first vessel containing a liquid concentrate for preparing a beer; a second vessel containing an alcoholic liquid; a source of water; a source of pressurized carbon dioxide; a reconstitution unit; a dispensing unit for dispensing the alcoholic beer; wherein the device is operable (i) to form a reconstituted beer comprising water from the source of water, carbon dioxide from the source of pressurized carbon dioxide, liquid concentrate from the first vessel and alcoholic liquid from the second vessel, in the reconstitution unit and (ii) to dispense the reconstituted beer from the dispensing unit; wherein the liquid concentrate in the first vessel an ethanol content of 0-1% ABV; and wherein the alcoholic liquid in the second vessel contains 12-100 wt. % ethanol and 0-88 wt. % water, ethanol and water together constituting 80-100 wt. % of the alcoholic liquid.

An alternative aspect of the invention relates to a device wherein the source of water and the source of pressurised carbon dioxide are replaced by a source of carbonated water and the device is operable to form a reconstituted beer comprising water from the source of carbonated water, liquid concentrate from the first vessel and alcoholic liquid from the second vessel in the reconstitution unit.

The aforementioned devices can be used to prepare a reconstituted beer of superior quality. The use of an essentially alcohol-free concentrate offers the advantage that the stability of the concentrate is substantially improved.