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 method is described and shown for operating a filling device with a filling valve for controlling a medium flow, with a discrete-time sampling flow sensor for measurement-based capture of the medium flow discharged by the filling valve and with a controller for actuating the filling valve, wherein the control unit controls the filling valve to perform a filling process with a defined target filling quantity, taking into account the measured actual filling quantity, which is determined with the aid of the flow measurement values captured by the flow sensor. A measurement error caused by the discrete-time sampling of the flow measurement is reduced by synchronizing the start of the filling process between the filling valve and the flow sensor so that the first sampled flow measurement value of the flow sensor has a defined time relationship to the initial opening of the filling valve during the filling process.

Beverage dispensers, systems, and methods are provided for producing a beverage flavored mixture/solution based on instructions from a mobile device (also referred to as an electronic device) and without requiring a user to touch the beverage dispenser (e.g., reducing the spread of germs through touching shared surfaces). The beverage dispensers, systems, and methods described may also be advantageous in allowing for monitoring of use of a beverage dispenser, billing users, and tracking liquid intake. The beverage dispensers, systems, and methods may enable a greater tracking and control compared to conventional beverage dispensers.

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.

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 system for transporting beverage includes a container, an output port, a first length of tubing, a first gas source, and a valve. The container has a volume of beverage disposed therein. The first length of tubing has a first end and a second end. The first end of the first length of tubing is fluidly coupled to the container. The second end of the first length of tubing is fluidly coupled to the output port. The first gas source is fluidly coupled to the container via a second length of tubing. The second gas source is fluidly coupled to the first length of tubing. The valve has at least a first port and a second port. The first port of the valve is fluidly coupled to the first length of tubing. The second port is fluidly coupled to a clearing fluid source.

A beverage apparatus, the beverage apparatus being hand-holdable by a user of the beverage apparatus 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. The beverage apparatus can include various additional features.

Flavor and additive delivery systems and methods for beverage dispensers are disclosed. An example beverage dispenser includes flavor containers configured to contain flavor mixtures, flavor tags each of which is fixed to a respective one of the flavor containers, flavor sensors each of which is positioned to read tag information from a respective one of the flavor tags to monitor the respective one of the flavor containers, memory configured to store instructions related to dispensing water and the flavor mixtures, and a processor. The processor is configured to detect, based on the tag information collected by the flavor sensors, whether any of the flavor containers is at least one of expired, counterfeit, or out-of-position. The processor is configured to disable use of each of the flavor containers that are detected to be at least one of expired, counterfeit, or out-of-position.

A system for transporting beverage includes a container, an output port, a first length of tubing, a first gas source, and a valve. The container has a volume of beverage disposed therein. The first length of tubing has a first end and a second end. The first end of the first length of tubing is fluidly coupled to the container. The second end of the first length of tubing is fluidly coupled to the output port. The first gas source is fluidly coupled to the container via a second length of tubing. The second gas source is fluidly coupled to the first length of tubing. The valve has at least a first port and a second port. The first port of the valve is fluidly coupled to the first length of tubing. The second port is fluidly coupled to a clearing fluid source.

Cartridge loaders for fluid mixture dispensing systems are disclosed. One disclosed fluid mixture dispensing system comprises an interface surface, a cartridge receiver carriage, and an actuator configured to depress the cartridge receiver carriage towards the interface surface to load a cartridge. The fluid mixture dispensing system is configured to apply continuous downward pressure on the cartridge towards the interface surface when the cartridge is loaded and is in contact with the interface surface.