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 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 water valve having a housing defining an inlet and an outlet and a flow path extending therethrough, a pressure sensor configured to sense a water pressure at the inlet, a valve member situated within the flow path to open and close the flow path, a solenoid actuator, and a controller coupled to the pressure sensor to read the water pressure at the inlet and coupled to the solenoid to open and close the valve is provided. The controller determines an amount of time to hold the valve open in order to dispense an amount of water based on the water pressure. The controller commands the solenoid to open and close the valve to dispense the amount of water regardless of the water pressure. The controller is also configured to open the valve to reduce inlet pressure and prevent failure thereof.

A refrigerator includes a cabinet defining a fresh food compartment and a door pivotally mounted to the cabinet and including an interior surface in communication with the fresh food compartment when the door is closed. A shelf unit is disposed adjacent the interior surface of the door, and a container is supported by the shelf unit. A fill mechanism is positioned vertically above the container and the container is configured to receive liquid from the fill mechanism. A sensor is configured to sense a property of the container or liquid received in the container. A control is in communication with the sensor and regulates a dispensing of liquid into the container based upon the sensed property. The sensor utilizes a capacitive sensor located adjacent to the container.

An example method comprises receiving a control signal to open a first valve of a compressible liquid container within an airtight pressurized container, retrieving a first dispensing profile, each dispensing profile indicating at least one valve and, for each valve, a predetermined period of time for keeping a particular valve open, each of the valves controlling transport of contents a different compressible liquid container contained within the airtight pressurized container to a dispensing system, for each of the one or more valves identified in the first dispensing profile: opening the particular valve identified in the first dispensing profile for the particular predetermined period of time to transport contents over a first liquid transport conduit that is coupled to a particular releasable coupling and the particular valve, and closing the particular valve after the particular predetermined period of time to dispense an amount of contents of the particular compressible liquid container.

A refrigerator includes a cabinet defining a fresh food compartment and a door pivotally mounted to the cabinet and including an interior surface in communication with the fresh food compartment when the door is closed. A shelf unit is disposed adjacent the interior surface of the door, and a container is supported by the shelf unit. A fill mechanism is positioned vertically above the container and the container is configured to receive liquid from the fill mechanism. A sensor is configured to sense a property of the container or liquid received in the container. A control is in communication with the sensor and regulates a dispensing of liquid into the container based upon the sensed property. The sensor utilizes a capacitive sensor located adjacent to the container.

A refrigerator includes a cabinet defining a fresh food compartment and a door pivotally mounted to the cabinet and including an interior surface in communication with the fresh food compartment when the door is closed. A shelf unit is disposed adjacent the interior surface of the door, and a container is supported by the shelf unit. A fill mechanism is positioned vertically above the container and the container is configured to receive liquid from the fill mechanism. A sensor is configured to sense a property of the container or liquid received in the container. A control is in communication with the sensor and regulates a dispensing of liquid into the container based upon the sensed property. The sensor utilizes a capacitive sensor located adjacent to the container.

A refrigerator includes a cabinet defining a fresh food compartment and a door pivotally mounted to the cabinet and including an interior surface in communication with the fresh food compartment when the door is closed. A liquid dispenser is arranged on the interior surface of the door, and a container is supported on the door and configured to receive liquid from the liquid dispenser. A sensor is configured to sense a property of the container, and a control is in communication with the sensor. The control is configured to regulate dispensing of liquid into the container based upon the sensed property of the container. The sensor utilizes a magnetic sensing element located adjacent to the container.

A refrigerator includes a cabinet defining a fresh food compartment and a door pivotally mounted to the cabinet and including an interior surface in communication with the fresh food compartment when the door is closed. A liquid dispenser is arranged on the interior surface of the door, and a container is supported on the door and configured to receive liquid from the liquid dispenser. A sensor is configured to sense a property of the container, and a control is in communication with the sensor. The control is configured to regulate dispensing of liquid into the container based upon the sensed property of the container. The sensor utilizes a magnetic sensing element located adjacent to the container.

A method for operating a water dispenser, the water dispenser having a water supply, a carbon dioxide supply, an outlet for pouring water into a container placed below the outlet, a controller and a user interface, the method including the following steps, which are executed in response to an activation of the water dispenser via the user interface: determining a nominal value of a water volume (V) that is to be filled into the container determining a nominal value of a waiting period (WP) by means of the controller determining nominal values of a first partial volume (V1) and a second partial volume (V2) by means of the controller (V1+V2=V), in particular by determining a volume ratio (R) with R=V1/V for dividing the water volume (V) into the partial volumes (V1, V2) pouring the first partial volume (V1) through the outlet waiting through the waiting period (WP) pouring the second partial volume (V2) through the outlet.