An arrangement for brewing and dispensing fermented drinks, primarily beers, by portions using concentrates in a personalized, tailor-made manner that is fit for self-service. The arrangement is fitted with a primary alcohol unit and a secondary alcohol unit, which are suitable for adjusting the alcohol content for each portion and contain an alcohol and water mixture of a fermented liquid, and the controlling part is connected to at least one alcohol adjusting part that is suitable for setting the alcohol content of each portion of beverage. A fermented base concentrate and alcohol originating from the fermented beverage, left in and/or extracted from the base concentrate, is used as raw material, and the alcohol content of the beverage is adjusted by adding further alcohol, and the flavour of each portion of beverage is adjusted as desired.

A beverage apparatus and system is disclosed. The beverage apparatus is configurable to add flavors, minerals, vitamins, or other such additives to a source fluid, such as purified water, in response to a user's selection of settings, to provide a customized beverage. Advantageously, the beverage apparatus uses the purified water to cleanse the components that come into contact with the N additive as part of the preparation of each beverage and includes this cleansing wash as part of the beverage itself, thus providing a self-cleaning apparatus that does not require a separate drain.

A water purifier includes: a raw water flow path; a purified water flow path connected to the raw water flow path; at least one filter provided in the purified water flow path and to filter raw water flowing along the purified water flow path; a washing water flow path connected to the raw water flow path; a washing water generator configured to electrolyze the raw water to generate washing water; an optical sensor to output a value according to a degree of generation of bubbles included in the washing water; and a controller to control the washing water generator and at least one valve provided in at least one of the raw water flow path, the purified water flow path, and the washing water flow path to perform a washing operation, and identify whether an error has occurred in the washing operation based on an output from the optical sensor.

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.

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.

A method and apparatus is disclosed that cleans a plurality of beverage dispensers which sit in respective holsters. Cleaning solution conduits are oriented to spray cleaning solution towards respective tops of holsters. One or more fluid valves alternatively permit and block said cleaning solution to flow to said cleaning solution conduits, respectively. A power supply flow signals to the fluid valve, respectively, wherein the valve transitions between permitting and blocking flow responsive to transitioning of the flow signals, respectively. A transmitter signals the power supply to transition the flow signals to cause the fluid valve to permit the cleaning solution to flow to the cleaning solution conduits.

A method and apparatus is disclosed that cleans a plurality of beverage dispensers which sit in respective holsters. Cleaning solution conduits are oriented to spray cleaning solution towards respective tops of holsters. One or more fluid valves alternatively permit and block said cleaning solution to flow to said cleaning solution conduits, respectively. A power supply flow signals to the fluid valve, respectively, wherein the valve transitions between permitting and blocking flow responsive to transitioning of the flow signals, respectively. A transmitter signals the power supply to transition the flow signals to cause the fluid valve to permit the cleaning solution to flow to the cleaning solution conduits.

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

NZ, OM, PA, PE, PG, PH, PL, PT, QA, RO, RS, RU, RW, SA, SC, SD, SE, SG, SK, SL, ST, SV, SY, TH, TJ, TM, TN, TR, TT, TZ, UA, UG, US, UZ, VC, VN, WS, ZA, ZM, ZW.

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

NZ, OM, PA, PE, PG, PH, PL, PT, QA, RO, RS, RU, RW, SA, SC, SD, SE, SG, SK, SL, ST, SV, SY, TH, TJ, TM, TN, TR, TT, TZ, UA, UG, US, UZ, VC, VN, WS, ZA, ZM, ZW.

Systems and methods are provided for dispensing ice and at least one liquid, and related cleaning processes. In one embodiment, the system comprises an ice bin for storing a quantity of ice particles, a dispensing tube for carrying at least a first liquid, and a discharge chute in communication with a discharge outlet, wherein the discharge chute is disposed upstream of the discharge outlet. An outlet end of the dispensing tube is positioned within a portion of the ice bin at a location aligned above the discharge outlet. The ice particles and the first liquid are dispensed through the discharge outlet separately or at the same time.