Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example beverage dispenser includes flavor containers configured to contain flavor mixtures, a manifold configured to blend water with flavor mixtures, a flowrate sensor configured to detect a current flowrate of the water flowing to the manifold, memory configured to store instructions related to dispensing the water and the flavor mixtures, and a processor. The processor is configured to receive a request for a selected beverage, identify a ratio between the water and one or more of the flavor mixtures for the selected beverage, transmit a water control signal to cause the water to flow at a requested water flowrate, and transmit one or more first flavor control signals to cause one or more of the flavor mixtures to flow from the flavor containers based on the ratio.

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.

Methods and systems for accurately and securely dispensing high value beverages are presented herein. A beverage distribution system includes one or more replaceable beverage cartridges mounted to a beverage dispensing device. Each of the beverage cartridges includes a fluid reservoir with an output port, an output control valve, a flowmeter, and a local controller. The local controller receives signals from the flow meter and determines a cumulative amount of beverage fluid dispensed from the beverage cartridge based on the received signals. In one embodiment, the beverage dispensing device includes a fluid pump and a master controller. The master controller also estimates the cumulative amount of beverage fluid dispensed from each beverage cartridge based on control commands communicated to each beverage cartridge. If a difference between the estimated cumulative amounts of fluid dispensed from a beverage cartridge exceeds a predetermined threshold value, an alert is generated.

A water dispenser and a method of controlling a water dispenser are provided. The water dispenser may control power output of an induction heater having a hot water module based on changes in flow rate of water supplied or a temperature of water discharged.

A beverage monitoring system is provided for a beverage system that includes a pressurized gas source, pressurized gas regulators, pressurized gas distribution lines, beverage distribution lines, beverage vessels, and beverage dispensers. The beverage monitoring system comprises at least one gateway that includes a processor, a network interface connected to dispensers, and a network interface connected to sensor assemblies. The beverage monitoring system also includes a sensor assembly. The sensor assembly is configured to run diagnostics to diagnose a potential problem with the line, or provide consolidated information for correlation with point-of-sale data.

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.

The present invention discloses a beverage dispenser, including: an inlet connected to a water source; an outlet for dispensing the water to a user vessel; at least one filter element having an input and an output for filtered water; a pump for pumping water to the input of the filter element; a flow sensor connected between the inlet and the outlet, wherein the flow sensor determines the actual flow rate of the water; at least one water preparation element connected between the output for outputting filtered water and the outlet and adapted to prepare the water for drinking by a human, wherein the water preparation element comprises a water preparation rate input by which the water preparation rate of the water preparation element can be controlled; and a controller connected to the water preparation rate input of the water preparation element and the flow sensor, wherein the controller controls the water preparation rate of the water preparation element by a signal to the water preparation rate input such that the water preparation rate is proportional to the actual flow rate.

A portable hydration system and various components are disclosed. The system utilizes a pump to transfer potable liquid (e.g. water) from a liquid container to a user during challenging activities (e.g. endurance motorcycle riding).

Beverage dispensing system (10) comprising: —one or more pressure chambers comprising a connectable base (14) part and lid (12) defining a sealed inner space (16) for accommodating and encapsulating a —40 collapsible beverage container (18) having a beverage outlet connectable to the base part (14), —a tapping device (34) comprising one or more tapping heads (36) for extracting the beverage from the collapsible beverage to container(s), —a tapping line (28) extending from said base part (14) to said tapping device, said tapping line comprising one or more beverage lines, and —at least one measuring device (56) configured for monitoring at least one physical quantity of the tapping line, sealed inner space, base part, lid and/or collapsible beverage container, said measuring device configured to have a sampling rate of at least 10 Hz, wherein the beverage dispensing system is configured for —processing data from the measuring device, and —detecting an event in the system by continuously analysing data from the measuring device.

A liquid sales management device is to be added to a liquid supply system supplying a liquid within a storage container to a dispensing device through a supply pipe with the liquid pressurized in order to cool the liquid in the dispensing device, and dispensing the cooled liquid to a drinking container. The liquid sales management device includes an actual flow rate determining unit that determines an actual measured flow rate of the liquid dispensed into the drinking container from the dispensing device, a cleaning mode detection unit that detects a cleaning mode in the liquid supply system, and a consumption flow rate acquisition unit that determines an actual consumption of the liquid based on the number of cycles of the cleaning mode, a known liquid amount consumed in one cycle of the cleaning mode in the liquid supply system, and the actual measured flow rate.