The present invention provides a beverage machine with at least three distinct zones 1, 3, 4. A first zone 1 for storing a liquid or semi-liquid product at ambient temperature, a second zone 3 for processing the stored product, in particular for cooling the product to a predetermined serving temperature, and a third zone 4 for storing the cooled product and maintaining it at the predetermined serving temperature. From the third zone 4 an iced beverage can be dispensed.

A system and method for determining a liquid level in a vessel is described. Embodiments of the system can include a liquid level measuring assembly, a user device, and a vessel. The liquid level measuring assembly can include an ultrasonic sensor assembly, a control module, and a mount body configured to place the ultrasonic sensor assembly proximate a bottom of a vessel. Typically, the system can be implemented with a vessel having a substantially cylindrical shape and including a chime. The mount body can be adapted to removably couple to the inside of the chime of the vessel.

A liquid product distribution network includes a keg distribution monitoring and reporting apparatus associated with a keg. The apparatus includes a radio transmitter device and sensing circuitry for sensing and communicating physical properties associating with the keg. A top or bottom chime of keg physically protects the sensing circuitry during keg distribution in the keg distribution network. The apparatus also includes a battery power supply unit fitted within and protected by the top or bottom chime. The apparatus further includes a unique identifier associated with the sensing and reporting device. The apparatus further includes a mobile communications device is configured to identify the keg based on the unique identifier associated with the sensing and reporting device embedded therein, and receive and process the radiofrequency signals from the radiofrequency signal transmission circuitry of the identified keg passively and without user interaction, for monitoring the physical properties and location of the keg.

A liquid product dispensing container device for affixes to a liquid product dispensing container, such as a beer keg, for monitoring, controlling and/or optimizing flow of a liquid product delivered to consumers from the liquid product dispensing container. The liquid product dispensing container device includes a casing for attaching it to the liquid product dispensing container. The liquid product dispensing container device includes a power source, a radio transmitter circuit, a radio/processing module processing radio signal transmissions of information relating to the liquid product dispensing container. An antenna associates with the radio/processing module for sending and receiving the radio signal transmissions between the radio/processing module and at least one stationary reader and/or mobile device.

A refrigerator having a carbonated water production module integrally provided with a carbon dioxide gas cylinder having carbon dioxide gas stored therein and a carbonated water tank to mix purified water with the carbon dioxide gas to produce carbonated water. The carbonated water production module is mounted to the rear surface of the door, and thus it may be cooled by cool air in the refrigeration compartment and be easy to access, and thereby repair and replacement thereof is facilitated. The dispenser includes a carbonated water discharge channel into which carbonated water from the carbonated water tank is discharged, and a purified water discharge channel into which purified water from the water tank is discharged. Since the purified water discharge channel does not pass through the carbonated water tank, a user is allowed to selectively dispense purified water or carbonated water anytime.

Disclosed herein is a refrigerator capable of producing carbonated water and a control method thereof. The refrigerator includes a carbonated water tank to store carbonated water a carbon dioxide gas supply valve to open/close a carbon dioxide gas flow path to guide carbon dioxide gas from a carbon dioxide gas cylinder to the carbonated water tank, and a carbonated water tank pressure sensor to detect an internal pressure of the carbonated water tank.

Consumption safety and quality assurance features for fluid mixture dispensing systems, such as a beverage dispensing device, are disclosed. A disclosed beverage dispensing device includes a final dispense chamber and a dispenser for the final dispense chamber. The beverage dispensing device is configured to mix a beverage and store the beverage in the final dispense chamber prior to a final dispense of the beverage from the beverage dispensing device. The beverage dispensing device is further configured to determine at least one parameter of the beverage. The dispenser is locked if the at least one parameter does not satisfy an expected standard and unlocked if the at least one parameter does satisfy the expected standard. The expected standard can be a safety standard or a quality standard.

A supply device for one or more beverage-dispensing machines (1a, 1b) is provided, having a holding space for the insertion of at least two storage containers (5a, 5b) for liquid foods, in particular milk, which storage containers can be connected to the one or more beverage-dispensing machines by food lines (4a, 4b, 4a′, 4b′). The supply device (2) has a cooling device (10) for the temperature control of liquid foods contained in the storage containers to a specifiable target temperature. A thermally conductive, in particular metal, contact surface (8a, 8b) is provided for each of the food containers (5a, 5b), which contact surface is in thermally conductive contact with a thermally conductive outer wall (7a, 7b), in particular bottom surface, of the storage container in question when the storage container is installed, in order to cool the contents of the storage container. In addition, the thermally conductive contact surfaces can be cooled by the cooling device (10) by separately controllable cooling circuits (9a, 9b).

A closing valve for a container for a fluid includes an outer jacket connected or connectable to an opening in the container or forming part of the container. An inner jacket is accommodated inside the outer jacket and has an opening through which the fluid can be fed to or withdrawn from the container. A closing element is positioned inside the inner jacket or between the inner jacket and the outer jacket and movable between at least a first position closing the opening and a second position clearing the opening, wherein at least the closing element is made from a polymer material. The closing element comprises a sealing member and a spring, which urges the closing element into the first position.

Keg sensors and keg sensor assemblies are disclosed. In some embodiments, the keg sensor may include a main body and a first connector attached to the main body and configured to be connected to a keg dispensing coupler. The keg dispensing coupler may be configured to be moved between a closed position and an open position; The keg sensor may additionally include a second connector attached to the main body and configured to be connected to a valve of a keg. The keg sensor may further include a sensor assembly attached to the main body and configured to detect one or more operating parameters of liquid dispensed, via the keg dispensing coupler, from the keg through the keg sensor. In some embodiments, the keg sensor assembly may include a keg sensor and a stack cage assembly. The stack cage assembly may include a cage sized to surround the keg sensor.