A water dispensing system includes: at least one flow control valve connected to a water pipe, and comprising a flow meter configured to measure an amount of water flowing in the water pipe and a solenoid valve configured to control a flow of the water by allowing or blocking the flow of the water in the water pipe; a controller configured to control dispensing of the water from one end of the water pipe by electrically communicating with each of the flow meter and the solenoid valve; and a switch configured to provide an interface for a user to control an operation of the water dispensing system.

A water purifier is provided. The water purifier according to an aspect of the present invention includes a housing; a filter provided inside the housing to filter raw water to produce purified water; a water outlet member that ejects purified water generated in the filter to the outside of the housing; a control valve configured to control water ejection amount ejected through the water outlet member; a factor value measurement sensor configured to obtain information on water ejection amount influencing factors that may affect the water ejection amount; an input panel provided on one side of the housing to receive input of at least one of first user input information to allow to be switched to a state where a user can set the water ejection amount, second user input information on a user water ejection amount which is a water ejection amount that the user wishes to set, and user water ejection start information to ensure that water is ejected as much as the user water ejection amount; and a processor configured to control the water ejection amount using information on the water ejection amount influencing factors when the user water ejection start information is input, wherein the processor may obtain a factor value at the time of setting of the water ejection amount influencing factor when the user water ejection amount is input, obtain a factor value at the time of water ejection of the water ejection amount influencing factor when the user water ejection amount is input, and control the control valve to eject water equal to the user water ejection amount using the factor value at the time of setting, the factor value at the time of water ejection, and the second user input information.

A fluid line monitoring and control assembly for detecting foaming and terminating flow in a beverage line includes a valve and a flow meter, which are insertable in-line with a conduit connecting a storage vessel to a dispensing tap, such that the valve is positioned proximate to the storage vessel. The valve can close the conduit to prevent flow of a beverage therethrough. The flow meter quantifies flow and can detect at least one parameter indicative of each of a liquid state and a foam state of the beverage and generates first and second signals, corresponding thereto. A controller receives the first signal and the second signal from the flow meter. Foam in line programming code positioned on the controller enables the controller to selectively actuate the valve to close the conduit upon receipt of the second signal. The valve limits flow of the beverage in the foam state past the valve.

A dispensing apparatus (20; 300; 400) comprises: a freezing cylinder (40); a water flowpath (526); a first controllable valve (130) along the water flowpath; a syrup flowpath (528), merging with the water flowpath and proceeding as a water/syrup flowpath (552) to the freezing cylinder; and a second controllable valve (132) along the syrup flowpath. The first controllable valve and the second controllable valve each comprise: a valve body (144; 432) having a cartridge compartment (164,166), an inlet (176) to the cartridge compartment, and an outlet (178) from the cartridge compartment; and a valve cartridge (162). The valve cartridge comprises: a cartridge body (200) mounted in the cartridge compartment; a valve element (222) carried by the cartridge body and shiftable between a first condition permitting communication between the inlet and the outlet and a second condition blocking communication between the inlet and the outlet; and a solenoid (224) carried by the cartridge body and coupled to the valve element to drive movement of the valve element.

A material dispensing device includes: a target nozzle for dispensing a target material to a target container; a pump arranged to operably extract the target material from the material container and to operably push the target material to flow toward the target nozzle; a material drainage port; a flow direction switch device, coupled with the target nozzle and the material drainage port, and arranged to operably receive the target material; and a control circuit. When the material dispensing device needs to output the target material to the target container, if the control circuit determines that a quality of the target material inside the material dispensing device is acceptable, the control circuit controls the flow direction switch device to guide the target material to flow toward the target nozzle, so as to dispense the target material into the target container through the target nozzle.

A liquid-dispensing device includes: a table, including a body and a plate, the body including three casks containing a liquid, each cask including a shell in which a pouch, made of a flexible material and containing the liquid, is positioned; three draft circuits, extending from each cask to three dispensing taps; a system for cooling the draft circuit; three pressurized draft systems for drawing the liquid from each cask, the draft system including a solenoid valve in each draft circuit, between the cask and the tap; a system for managing the device, the managing system being provided to control dispensing by opening or closing the solenoid valve; and wheels enabling movement of the device. The plate includes: three liquid-dispensing taps; and a unit for interacting with the management system, which is suitable for interfacing with the liquid-dispensing control. The managing system is connected to a database via a connector.

A beverage apparatus hand-holdable by a user to be portable, can include a beverage chamber housing that includes a chamber for storing a consumable liquid. The beverage apparatus can include a dispensing assembly that includes a receptacle. The receptacle can retain a vessel. The vessel can include an electronic tag and can contain an additive. The dispensing assembly can be operatively controllable by a controller to output the additive from the vessel into the consumable liquid. The beverage apparatus can include one or more sensors, devices, or assemblies that can be used to detect a volume of liquid in the chamber or a liquid level in the chamber. The beverage apparatus can include an apparatus computer processor portion (ACP) and an apparatus database portion.

A water dispensing system includes: at least one flow control valve connected to a water pipe, and comprising a flow meter configured to measure an amount of water flowing in the water pipe and a solenoid valve configured to control a flow of the water by allowing or blocking the flow of the water in the water pipe; a controller configured to control dispensing of the water from one end of the water pipe by electrically communicating with each of the flow meter and the solenoid valve; and a switch configured to provide an interface for a user to control an operation of the water dispensing system.

A dispensing system for a beverage comprises in a tap system a bore for housing a duct. Along the bore, close to or on the duct, at least two electrodes are provided such that at least at some locations along the duct, the two electrodes are provided opposite to one another with the duct in between, thus constituting a capacitor. An oscillating signal is provided to one electrode and a signal is read out from the other electrode. As a beverage is drawn through the duct in a container, capacitance of the capacitor changes. The flowing beverage may have different characteristics, but capacitance may also change as the beverage in the duct is in conducting contact with a container that may be in contact with an earth contact. The change of capacitance results in a change of the amplitude of a detection circuit connected to the second electrode.

A beverage apparatus hand-holdable by a user to be portable, can include a beverage chamber housing that includes a chamber for storing a consumable liquid. The beverage apparatus can include a dispensing assembly that includes a receptacle. The receptacle can retain a vessel. The vessel can include an electronic tag and can contain an additive. The dispensing assembly can be operatively controllable by a controller to output the additive from the vessel into the consumable liquid. The beverage apparatus can include one or more sensors, devices, or assemblies that can be used to detect a volume of liquid in the chamber or a liquid level in the chamber. The beverage apparatus can include an apparatus computer processor portion (ACP) and an apparatus database portion.