A dispensing nozzle assembly is provided including a nozzle member provided with one or more dispensing apertures to allow fluid to be dispensed therefrom in use. Closure means are provided on or associated with the nozzle member and movable relative thereto between a closed position, wherein the closure means closes the dispensing apertures and fluid cannot be dispensed from the dispensing apertures, and an open position, wherein the closure means are moved at least partially clear of the dispensing apertures and fluid can be dispensed through the dispensing apertures in use. Switch means are moveable between an on position for allowing fluid to flow into the nozzle member for dispensing through the dispensing apertures in use, and an off position for preventing fluid flowing into the nozzle member in use. The switch means are arranged such that movement of the closure means relative to the nozzle member moves or actuates the switch means between the on and off positions in use.

Provided is a water carbonation unit including: at least one water feed and at least one pressurised carbon-dioxide feed; a merging duct extending between a first, closed end and a second end, the at least one water feed and at least one carbon-dioxide feed opening into said duct at said first end; said second end opening into a mixing chamber linked to a carbonated water outlet; the carbonated water outlet configured to restrict outflow of carbonated water from the chamber to thereby maintain pressure within the chamber while carbonated water flows out of the carbonated water outlet.

A beverage discharger may include a dispenser case; a channel body at least partially disposed in the dispenser case, the channel body having a first dispenser channel defined therein that communicates with a beverage discharge channel; a discharge body coupled to the channel body and having a second dispenser channel defined therein that communicates with the first dispenser channel, the discharge body extending vertically in an elongated manner; an ascending and descending body connected to the dispenser case in an ascending and descending manner; a shaft connected to the ascending and descending body to ascend and descend with the ascending and descending body, the shaft having, at a bottom portion, a packing that opens and closes the second dispenser channel; and at least one guide rib formed on an inner face of the discharge body to guide the bottom portion of the shaft.

A soda carbonation and dispensation system and method are provided. The system includes a carbonated water pump and motor assembly operable to draw fresh water into carbonator tanks and circulate the water through a chiller system. A carbon dioxide source is connected to the carbonator tanks to produce carbonated water. The system also includes a water level sensor connected to a controller, a plurality of syrup containers, a syrup pump, syrup regulator valves, a brix capacitor, a dispensing tower and faucets connected to the dispensing tower housing. The controller operates the water pump and motor assembly to maintain a water level within a predetermined range and to maintain continuous flow and refrigeration of the carbonated water, which optimizes carbonation. The brix capacitor receives chilled carbonated water and chilled syrup in separate lines. Carbonated water is circulated to the faucets through a manifold in the brix capacitor and then circulated back into the carbonator tanks. Valves are provided in the brix capacitor to manipulate carbonated water and syrup flow rates and pressures into the faucets. The system maintains the carbonated water and syrup at a refrigerated temperature and a predetermined maximum pressure. When a faucet is opened, the carbonated water and syrup mix as they flow laminarly into a container. The result is consistently optimum carbonation when the beverage is dispensed.

A soda carbonation and dispensation system and method are provided. The system includes a carbonated water pump and motor assembly operable to draw fresh water into carbonator tanks and circulate the water through a chiller system. A carbon dioxide source is connected to the carbonator tanks to produce carbonated water. The system also includes a water level sensor connected to a controller, a plurality of syrup containers, a syrup pump, syrup regulator valves, a brix capacitor, a dispensing tower and faucets connected to the dispensing tower housing. The controller operates the water pump and motor assembly to maintain a water level within a predetermined range and to maintain continuous flow and refrigeration of the carbonated water, which optimizes carbonation. The brix capacitor receives chilled carbonated water and chilled syrup in separate lines. Carbonated water is circulated to the faucets through a manifold in the brix capacitor and then circulated back into the carbonator tanks. Valves are provided in the brix capacitor to manipulate carbonated water and syrup flow rates and pressures into the faucets. The system maintains the carbonated water and syrup at a refrigerated temperature and a predetermined maximum pressure. When a faucet is opened, the carbonated water and syrup mix as they flow laminarly into a container. The result is consistently optimum carbonation when the beverage is dispensed.

Typical dispensers of liquids such as for beer often induce froth into the liquid as it is dispensed. This is not always desirable especially if too much froth is produced leading to waste. A liquid dispensing device (10) comprising a plurality of tubes (30) each tube having a diameter less than 2 mm is described to address the issue of over-frothing.

A beer dispensing faucet is configured to be attached to a shank connector. The shank connector has a connecting member and an internal passageway having an outlet opening positioned within the connecting member. The dispensing faucet has a housing defining a central conduit having an inlet opening and an outlet opening. The housing defines a valve seat in the central conduit and further has an aperture in communication with the central conduit. The inlet opening is dimensioned to correspond in size to the outlet opening of the internal passageway and further configured to be positioned in confronting relation to the outlet opening of the internal passageway. The housing has a connecting member configured to cooperate and connect to the connecting member of the shank connector. A valve stem is positioned in the aperture. The valve stem has a first position wherein the valve stem is engaged with valve seat to define a closed faucet position. The valve stem has a second position away from the valve seat to define an open faucet position.

A liquid dispenser comprise a nozzle comprising an inlet in fluid communication with an outlet to form a flow path, a thermistor in fluid communication with the inlet, an actuator rod comprising a gasket rod tip viton, at least one centering pin to center the actuator rod in at least a portion of the flow path, a flowmeter in fluid communication with the inlet, a double acting pneumatic cylinder comprising a first pneumatic inlet and a second pneumatic inlet operatively connected to the actuator rod, and a switch lever operatively coupled to a micro switch, wherein the nozzle opens when gas enters the first pneumatic inlet when the switch lever is activated by pressing on the micro switch and closes when gas enters the second pneumatic inlet when the switch lever is deactivated. Portable and non-portable liquid dispensing systems comprising the liquid dispenser are also described.

A liquid dispenser comprise a nozzle comprising an inlet in fluid communication with an outlet to form a flow path, a thermistor in fluid communication with the inlet, an actuator rod comprising a gasket rod tip viton, at least one centering pin to center the actuator rod in at least a portion of the flow path, a flowmeter in fluid communication with the inlet, a double acting pneumatic cylinder comprising a first pneumatic inlet and a second pneumatic inlet operatively connected to the actuator rod, and a switch lever operatively coupled to a micro switch, wherein the nozzle opens when gas enters the first pneumatic inlet when the switch lever is activated by pressing on the micro switch and closes when gas enters the second pneumatic inlet when the switch lever is deactivated. Portable and non-portable liquid dispensing systems comprising the liquid dispenser are also described.

A beer dispensing faucet is configured to be attached to a shank connector. The shank connector has a connecting member and an internal passageway having an outlet opening positioned within the connecting member. The dispensing faucet has a housing defining a central conduit having an inlet opening and an outlet opening. The housing defines a valve seat in the central conduit and further has an aperture in communication with the central conduit. The inlet opening is dimensioned to correspond in size to the outlet opening of the internal passageway and further configured to be positioned in confronting relation to the outlet opening of the internal passageway. The housing has a connecting member configured to cooperate and connect to the connecting member of the shank connector. A valve stem is positioned in the aperture. The valve stem has a first position wherein the valve stem is engaged with valve seat to define a closed faucet position. The valve stem has a second position away from the valve seat to define an open faucet position.