A beverage dispensing headwear having a ring toss shaft affixed thereto. A pair of container holders is affixed on opposing sides of a helmet. A three-way valve is fastened to the helmet, wherein a first and second intake tube are fluidly connected to the three-way valve on a proximal end and are configured to be inserted into a container held within one of the container holders on a distal end. An output tube is also fluidly connected to the three-way valve on a proximal end of the output tube. The output tube extends below the rim of the helmet at a distal end, wherein the distal end of the output tube is configured to be sucked on by a user. Additionally, shaft is affixed to the helmet.

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.

An ice-making water purifier includes a water tank unit, an instantaneous heating device, an extraction member, an ice-maker, a supply pump, an ice-making water inlet passage, an ice-making water supply valve, a flow rate sensor, and a controller configured to control driving of the supply pump and the opening and closing of the ice-making water supply valve such that purified water corresponding to a predetermined supply amount of ice-making water is supplied to the ice-maker on the basis of a flow rate value measured by the flow rate sensor. The controller controls the opening and closing of the channel such that purified water is preferentially supplied to the instantaneous heating device among the instantaneous heating device and the ice-maker.

The present application provides a beverage dispensing system for combining a number of ingredients. The beverage dispensing system may include an ingredient pouch, an ingredient storage tank, a pump, a nozzle, an inlet diverter valve upstream of the pump, and an outlet diverter valve downstream of the pump.

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 control system for controlling one or more tapping valves included in a beverage dispenser includes a telematic communication network with a cloud server and a gateway for selecting a tapping valve and connecting the telematics communication network to the selected tapping valve. The cloud server is configured to send a control signal to the gateway and the gateway is configured to verify which tapping valve the control signal is directed to and forward the control signal to the tapping valve. The control logic unit of each tapping valve is configured to receive the control signal and execute a command and/or modify one or more parameters of a set of parameters and/or add one or more further parameters to the set of parameters.

A beverage dispensing system, has: a reservoir; a line connected to the reservoir; a tap connected to the line; a first valve connected to the line downstream of the reservoir, the first valve having a first open configuration and a first closed configuration; and a second valve connected to the line, the second valve having a second open configuration and a second closed configuration, the second valve being in the second closed configuration when the first valve is in the first closed configuration, when in the second closed configuration, the second valve blocking fluid communication between the tap outlet and the first valve, the second valve being in the second open configuration when the first valve is in the first open configuration to connect the reservoir to the tap outlet through the first valve and the second valve.

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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Systems and methods for reducing the overall current draw of a fluid mixture dispensing device are disclosed. A disclosed system includes a mixing area, a set of ingredient reservoirs, and a set of electromechanical valves. The set of electromechanical valves are in a one-to-one correspondence with the set of ingredient reservoirs, and fluidly connect the set of ingredient reservoirs and the mixing area during a respective set of dispense times. The system further includes a controller programmed to actuate at least two valves from the set of electromechanical valves to dispense, to the mixing area, at least two ingredients from the ingredient reservoirs associated with the at least two valves. The controller is programmed to actuate the at least two valves in sequence with partially overlapping dispense times and without overlapping opening times.

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.