A system for sensing empty soft drink syrup containers in a soda pop dispensing arrangement is provided that includes at least one soft drink syrup container; a mixing station for mixing water and CO2 with soft drink syrup to make a soda pop mixture; a pump for pumping soft drink syrup to the mixing station and beyond to be dispensed; a CO2 container providing CO2 gas; and a soda pop dispenser apparatus. The system also includes a first tubing transmission line extending between the soft drink syrup container and the pump for carrying soft drink syrup, a second tubing transmission line for carrying soft drink syrup between the pump and the mixing station, and a third tubing transmission line extending between the mixing station and the soda pop dispenser for carrying soda pop to be dispensed. An optic sensor is located and spliced in the first tubing transmission line for sensing when the first tubing transmission line is devoid of soft drink syrup, and a signal indicator electrically connected with the optic sensor provides a signal indicating when the first tubing transmission line is devoid of syrup.

A detection device for detecting that a source is sold-out for a beverage dispenser, the beverage dispenser dispensing from the source via a valve controlled by a solenoid. A circuit board is configured to be positioned on the valve proximal to the solenoid. A detector is coupled to the circuit board, where the solenoid creates a magnetic field when dispensing from the valve, and where the detector detects the magnetic field created by the solenoid and consequently produces an electrical output. A control system is coupled to the circuit board in communication with the detector. The control system is configured to access threshold data and to compare the electrical output of the detector to the threshold data. The control system indicates that the source is sold-out based upon the comparison of the electrical output to the threshold data.

A beverage infusion apparatus includes: (a) a mixer for mixing a beverage concentrate and water to form a diluted concentrate, wherein the water is provided at a water pressure during operation sufficient to flow through the beverage infusion apparatus; (b) an infusion module for infusing a nitrogen containing gas into the diluted concentrate to form a gas infused beverage, wherein: (i) the infusion module comprises a gas draw venturi device for drawing the nitrogen containing gas into the diluted concentrate as a result of flow of the diluted concentrate through the gas draw venturi device to form the gas infused beverage; and (c) a dispensing valve for dispensing the gas infused beverage and constructed to move between an open position and a closed position, wherein: (i) the open position permits dispensing of the gas infused beverage from the beverage infusion apparatus; (ii) the closed position prevents dispensing of the gas infused beverage from the beverage infusion apparatus; and (iii) the dispensing valve is constructed to move between the open position and the closed position by a user of the beverage infusion apparatus. A method of forming a gas infused beverage is provided.

Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example manifold of a beverage dispenser includes a base defining a base cavity and configured to extend through an opening defined by an outer wall. The manifold includes a first housing coupled to the base and defining a housing cavity. The base cavity and the housing cavity are adjacent to each other to form a chamber. The manifold includes a body coupled to the first housing and defining a body cavity and angled apertures. The manifold includes an insert housing that is coupled to the body and extends at least partially through the body cavity. The manifold includes an insert housed within the insert housing and defining a water outlet for spraying water downward into the chamber. The angled apertures are configured to receive nozzles that extend at least partially into the chamber at the predefined angle.

A beverage maker may include a fermenter having a space therein to make a beverage; a fluid tank configured to contain fluid; a fluid supply pump connected with the fluid tank; a flow rate detection sensor disposed in a channel connected with the fluid supply pump to detect a flow velocity or a flow rate of fluid which is discharged through the channel by the fluid supply pump; and a controller configured to perform a plurality of operations related to making of a beverage or cleaning of an inside of the beverage maker. The controller may be configured to when an operation requiring a supply of fluid is ongoing from among the plurality of operations, turn on the fluid supply pump to discharge fluid contained in the fluid tank; detect a lack of fluid in the fluid tank based on a first flow velocity or a first flow rate detected by the flow rate detection sensor; and generate a fluid replenishment request for the fluid tank based on a result of detecting.

A management apparatus MA includes a pressure sensor 12 configured to detect a pressure of a gas cylinder 110 that supplies carbon dioxide gas to a beverage barrel 120 so as to supply the beverage from the beverage barrel 120 to the beverage server 150, and a control unit 20 configured to notify exchange of the gas cylinder 110 based on an output from the pressure sensor 12.

A water-dispensing device includes a cold water tank and a fill valve. The tank is in selective fluid communication with a water intake via the fill valve. The device further includes a cold dispensing valve, a spigot in selective fluid communication with the tank via the cold dispensing valve, an ozone generator in fluid communication with the tank, and a drip tray positioned beneath the spigot. The drip tray is in fluid communication with a drain via a drain hose. A controller is configured to perform a cleaning operation by: (i) activating the ozone generator to ozonate water stored in the tank, (ii) opening the cold dispensing valve to empty the tank by dispensing the ozonated water from the tank through the spigot and into the drip tray, and (iii) upon determining the tank is empty, opening the fill valve to refill the tank.

A system to accurately and cost effectively monitor the level of syrup in a BIB and ensure proper mixture.

A system and method detection of an empty keg is provided. Carbonated beverages from a keg communicates a carbonated alcoholic beverage to a Foam on Beer (FOB) detector. The FOB forms a reservoir and containing a float. Level detection sensors in operative communication with the float identifies the position and movement of the float. An keg's status can thereby be anticipated by float level and speed changes. A the FOB status can thereby operate a touchless tap including a control valve via a tap control board (TCB) that actuates the control valve. A controller in operative communication with the TCB communicates with the control valve, the actuation button and in communication with the level sensor.

There are provided a liquid supply system and a liquid loss reduction method capable of reducing a liquid loss caused when a liquid storage container is replaced. A liquid supply system (101) that transfers a liquid in a storage container (10) through a supply pipe (30), and dispenses the liquid from a dispensing outlet in a dispensing device (50). The liquid supply system includes a spout prevention unit (110) that is installed in the supply pipe, has a predetermined internal volume, and prevents a pressurized gas from being spouted from the dispensing outlet, a liquid-absence detection device (120) that is installed between the storage container and the spout prevention unit, and detects absence of the liquid in the storage container, and a control device (130) that is electrically connected to the liquid-absence detection device, and gives instructions for closing a flow path in the dispensing device in response to the detection of the absence of the liquid in the storage container.