A fluid mixture dispensing system using a membrane to seal multiple reservoirs is disclosed. The multiple reservoirs each contain a respective ingredient. The reservoirs are coupled to respective orifices in a plate. The respective ingredients are dispensable via the respective orifices. The membrane seals the respective orifices. The ingredients are dispensed into one or more channels formed between the membrane and the plate. In specific embodiments, the membrane is an integral part of a cartridge which contains the multiple reservoirs. In specific embodiments, the cartridge includes an inlet and an outlet. A solvent flows from the inlet to the outlet through the one or more channels, and the ingredients are dispensed into the solvent in the one or more channels.

A fluid mixture dispensing system using a membrane to seal multiple reservoirs is disclosed. The multiple reservoirs each contain a respective ingredient. The reservoirs are coupled to respective orifices in a plate. The respective ingredients are dispensable via the respective orifices. The membrane seals the respective orifices. The ingredients are dispensed into one or more channels formed between the membrane and the plate. In specific embodiments, the membrane is an integral part of a cartridge which contains the multiple reservoirs. In specific embodiments, the cartridge includes an inlet and an outlet. A solvent flows from the inlet to the outlet through the one or more channels, and the ingredients are dispensed into the solvent in the one or more channels.

Fluid mixture dispensing systems, devices and methods are disclosed. A device includes a set of pressurized ingredient reservoirs, a mixing area configured to receive at least one ingredient from the set of pressurized ingredient reservoirs, a pressure source, an accumulator chamber, a set of valves, and a controller. The controller is programmed to operate the set of valves to pressurize the accumulator chamber using the pressure source. The controller is further programmed to operate the set of valves to set a pressure in at least one of the set of pressurized ingredient reservoirs using the accumulator chamber.

Electronic pouring device (10) for dosing a pre-determined amount of liquid from a liquid container, the electronic pouring device including a housing (11), the housing including: an inlet opening (17) and an outlet opening (19) for the passage of liquid from the liquid container, a valve including a valve member (22) for controlling the passage of the liquid and a valve seat (20) at the outlet opening (19) for arresting the valve in a closed position, a liquid internal region (28) for accommodating the valve and for allowing the passage of the liquid through the housing (11), a dry internal region (30) for accommodating displacement structure for displacing the valve against the valve seat (20) into the closed position, or for displacing the valve away from the valve seat (20) into an opened position, the displacement structure including drive structure (25) and transmission structure (24), and a membrane (29) for separating the dry internal region (30) from the liquid internal region (28).

The disclosure generally relates to an automated modular dispensing platform for creating customized beverages (e.g., using various sauces, syrups, sweeteners, colors and/or flavors added to a base beverage). The automated dispensing platform may simultaneously aggregate beverage modifiers or ingredients (e.g., sweetener, flavor, and/or color) and facilitate automated, efficient cleaning cycles for modular beverage dispensers.

A networked system for providing and maintaining a set of liquid dispenser stations is described. The fluid dispensers communicate with a managing/supervisory cloud server via an interposed base station. The fluid dispensers communicate locally with the base station via wireless communication network links. The base station operates as an accumulator of status/usage information provided by the dispenser stations and bridge for passing information and control commands between the cloud server and the individual dispenser stations. The dispenser stations are configured with control processors (controllers) to facilitate performing a variety of local control operations associated with dispensing liquids that have been cooled (or heated) prior to dispensing by the dispenser stations. Additionally, the dispenser stations cooperatively operate with the cloud server (via the base station) to support a variety of real time control and maintenance operations relating to the dispenser stations operating at potentially thousands of distinct geographic locations.

A beverage dispensing system includes at least one bottle attachment portion, each having a first end providing a first attachment feature releasably engages a spout of a bottle; and an opposed second end providing a second attachment feature, in which a fluid passageway extends between the first end and the second end of the bottle attachment portion. A housing includes an upper surface defining at least one recess, each providing a housing attachment feature releasably engages the second attachment feature of a corresponding bottle attachment portion, each recess comprising an opening enabling fluid to pass therethrough; a support surface supports a receptacle thereon; and an actuator initiates dispensing of fluid from a bottle via the fluid passageway, through the opening of a recess, and into a receptacle supported on the support surface. An LED illuminates a portion of a bottle supported by or within the housing.

A beverage dispenser and method for operating a beverage dispenser may include receiving a handshake request from a mobile device of a user. A communications link may be established with the mobile device. Responsive to receiving control data associated with a beverage order from the mobile device, a physical function may be caused to be performed by the beverage dispenser.

Techniques for monitoring dispensed liquid include an intelligent spout that incorporates an IMU (Inertial Measurement Unit) for tracking its own orientation and movement in three-dimensional space. The spout has its own processor, memory, and wireless networking components, which support local data processing, data logging, and bi-directional wireless communication. Communication may be carried out with a server, with other spouts of like kind, and/or with other devices.

Ingredient dispensing systems and methods are disclosed. A disclosed system includes an ingredient reservoir and an electromechanical valve configured so that, when the electromechanical valve is activated, an ingredient is dispensed from the ingredient reservoir. The disclosed system also includes a current sensor configured to measure a current draw of the electromechanical valve. The disclosed system also includes a controller programmed to sample the current draw from the current sensor and to detect a dispense error of the electromechanical valve based on the sampled current draw.