An apparatus and a method are provided for a container filling and sealing production line to produce a target final pressure of liquid contents within containers during variable production line speeds. The container filling and sealing production line comprises a bottle filler that receives containers fabricated by manufacturing equipment and fills the containers with liquid contents. A cryogen dosing system adds a volume of a cryogen to the liquid contents. A bottle sealer seals the containers and entraps the cryogen and liquid contents, such that vaporization of the cryogen imparts the target final pressure of liquid contents within the containers. A communication line enables the bottle filler to pass information to the cryogen dosing system about upcoming changes in production speed such that the cryogen dosing system accordingly adjusts the volume of the cryogen.

Disclosed embodiments provide a liquid product dispensing system. Cans are transported onto a weigh plate. The weigh plate is coupled to a dispensing system such that, when the can is filled with product to a predetermined weight, the dispensing system stops the flow of product into the can. A transport system then moves the filled cans from the weigh plate and moves another set of empty cans onto the weigh plate, and the process continues, enabling high-speed production of canned beverages.

The present application provides a filling line for filling a container with one of a number of different beverages. The filling line may include a water circuit with a counter-pressure nozzle to fill the container with carbonated water and one or more micro-ingredient towers with a number of micro-ingredients therein positioned downstream of the counter-pressure nozzle to fill the container with the micro-ingredients.

A system and method of micro dosing containers on a conveying system is disclosed. The system includes a mixing tank to maintain suspended solids in a mixture; a dosing assembly to inject micro-doses of the mixture into bottles; a recirculation assembly to circulate the mixture from the supply tank to the dosing assembly and back to the supply tank; a power and controls operation assembly to supply the system with power, to provide the system with electromechanical control and/or to provide a user interface; and a stand to hold at least the supply tank, the portable dosing assembly, the recirculation assembly and/or the power and/or controls operation assembly.

A system and method for filling containers with a precise amount of fluid is disclosed. The system and method use artificial neural network logic to sense conditions and to control the two-valve dispensing unit based on the sensed conditions to fill containers with a precise amount of fluid. Using neural network logic combined with sensors and controllers for equipment eliminates the significant human effort and human errors associated with manually filling containers with fluid. Furthermore, the neural network can log data quicker and with more accuracy than a human manually logging data. The system and method use a two-valve dispensing unit to precisely fill and to prevent and clear clogs caused by fluid solidifying within the dispensing unit.

The disclosure concerns a dispensing system, having at least one dispense location with at least one dispensing head configured to dispense a beverage through a bottom portion of a container. In one aspect, the dispensing head may dispense a plurality of different beverage ingredients which a user may select to dispense a custom beverage. In another aspect the dispensing system comprises a modular dispensing system having a plurality of dispense locations each connected through piping to a central, remote ingredient system.

A system and method of micro dosing containers on a conveying system is disclosed. The system includes a mixing tank to maintain suspended solids in a mixture; a dosing assembly to inject micro-doses of the mixture into bottles; a recirculation assembly to circulate the mixture from the supply tank to the dosing assembly and back to the supply tank; a power and controls operation assembly to supply the system with power, to provide the system with electromechanical control and/or to provide a user interface; and a stand to hold at least the supply tank, the portable dosing assembly, the recirculation assembly and/or the power and/or controls operation assembly.

A device for filling a container with a filling product includes a filling valve for influencing the supply of the filling product into the container to be filled, generally during the transport, by means of a container transporting device, of the containers to be filled, a dosing valve for dosing a dosing product from a dosing product reservoir into the filling valve, and a main component reservoir for providing a main component at the filling valve. A dosing product changing device is provided for changing the dosing product in the dosing product reservoir during the filling operation.

Containers of the same or different size are filled with a non-viscous fluid at discrete stations, each container being filled independently of each other container. Multiple containers of the same or different size are positioned at multiple discrete stations, each container being at a different station. A non-viscous fluid is flowed into a container to a desired level. The level is sensed with a level sensor and the fluid flow stopped at the desired level. The fluid flow is reversed to prevent fluid dripping when a filled bottle is removed.

A method for filling a container with a filling product in a filling-product filling system having a control valve, having the steps: a differential pressure p.sub.v decreasing across the control valve; and regulating and/or controlling the control valve as a function of the differential pressure p.sub.v which has been determined.