A fluid integrating system (10) includes an integrating manifold (30) having two or more input fluid inlets (132) disposed at oblique angles relative to a center axis of the integrating manifold (30). The two or more input fluid inlets (132) intersect in the integrating manifold (30) to define an integrating chamber (112). The fluid integrating system also includes a pressure sensor (110) fluidly connected to the integrating chamber (112) that is operable to send a pressure signal indicative of the pressure of the fluid in the integrating chamber (112). A integrating controller (22) is operatively coupled to the two or more valves (60) and to the pressure sensor (110) and is operable to selectively control the flow of input fluids into the integrating chamber (112) by actuating the two or more valves (60) based on the pressure signal received from the pressure sensor (110).

A beverage maker includes: a container; a fermentation tank; a beverage dispenser including a lever configured to control dispensing of the beverage and a limit switch configured to be turned on and off based on manipulation of the lever; a beverage dispensing channel that connects the container and the beverage dispenser and that guides the beverage; a beverage dispensing valve disposed in the beverage dispensing channel; a pressure sensor that measures gas pressure inside the container; and a controller. The controller detects whether the limit switch is turned on, opens the beverage dispensing valve to dispense the beverage accommodated in the container through the beverage dispenser based on detecting that the limit switch is turned on, determines a gas pressure value corresponding to the gas pressure inside the container measured by the pressure sensor, and determines a dispensed amount of beverage based on the gas pressure value.

A fluid integrating system (10) includes an integrating manifold (30) having two or more input fluid inlets (132) disposed at oblique angles relative to a center axis of the integrating manifold (30). The two or more input fluid inlets (132) intersect in the integrating manifold (30) to define an integrating chamber (112). The fluid integrating system also includes a pressure sensor (110) fluidly connected to the integrating chamber (112) that is operable to send a pressure signal indicative of the pressure of the fluid in the integrating chamber (112). A integrating controller (22) is operatively coupled to the two or more valves (60) and to the pressure sensor (110) and is operable to selectively control the flow of input fluids into the integrating chamber (112) by actuating the two or more valves (60) based on the pressure signal received from the pressure sensor (110).

Non-electric fountain beverage dispensers for dispensing a variety of beverages without the use of electricity. The non-electric fountain beverage dispenser may include a gas container for storing a pressurized gas, a base liquid storage container for storing a base liquid, and a gas supply line that communicates pressurized gas from the gas container to the base liquid storage container and to a syrup storage container. Non-electric beverage dispenser further includes a mechanical dispensing valve in fluid communication with the base liquid storage container and the syrup storage container by means of a base liquid supply line and a syrup supply line, respectively, such that the mechanical dispensing valve is capable of selectively dispensing a mixture of the base liquid and the syrup. Non-electric fountain beverage dispenser further includes a non-electric cooling unit for cooling the base liquid without the use of electricity.

A post-mix beverage dispenser system with removable pumps is disclosed. The system includes a pump enclosure for receiving a plurality of beverage syrup pumps. Each beverage syrup pump may be easily removed from the enclosure and replaced in a tool-less manner. A sensor and control system for the plurality or removable pumps is also disclosed.

Non-electric fountain beverage dispensers for dispensing a variety of beverages without the use of electricity. The non-electric fountain beverage dispenser may include a gas container for storing a pressurized gas, a base liquid storage container for storing a base liquid, and a gas supply line that communicates pressurized gas from the gas container to the base liquid storage container and to a syrup storage container. Non-electric beverage dispenser further includes a mechanical dispensing valve in fluid communication with the base liquid storage container and the syrup storage container by means of a base liquid supply line and a syrup supply line, respectively, such that the mechanical dispensing valve is capable of selectively dispensing a mixture of the base liquid and the syrup. Non-electric fountain beverage dispenser further includes a non-electric cooling unit for cooling the base liquid without the use of electricity.

A beverage maker includes: a container; a fermentation tank; a beverage dispenser including a lever configured to control dispensing of the beverage and a limit switch configured to be turned on and off based on manipulation of the lever; a beverage dispensing channel that connects the container and the beverage dispenser and that guides the beverage; a beverage dispensing valve disposed in the beverage dispensing channel; a pressure sensor that measures gas pressure inside the container; and a controller. The controller detects whether the limit switch is turned on, opens the beverage dispensing valve to dispense the beverage accommodated in the container through the beverage dispenser based on detecting that the limit switch is turned on, determines a gas pressure value corresponding to the gas pressure inside the container measured by the pressure sensor, and determines a dispensed amount of beverage based on the gas pressure value.

A post-mix beverage dispenser system with removable pumps is disclosed. The system includes a pump enclosure for receiving a plurality of beverage syrup pumps. Each beverage syrup pump may be easily removed from the enclosure and replaced in a tool-less manner. A sensor and control system for the plurality or removable pumps is also disclosed.

The present application provides a beverage dispensing system for naturally carbonated beverages. The beverage dispensing system may include a cabinet with a cooling element and a heating element and a fermentation vessel positioned within the cabinet. The cooling element and the heating element maintain the fermentation vessel within a temperature range for a fermentation process therein and the cooling element cools the fermentation vessel to stop the fermentation process.

A post-mix beverage dispenser system with removable pumps is disclosed. The system includes a pump enclosure for receiving a plurality of beverage syrup pumps. Each beverage syrup pump may be easily removed from the enclosure and replaced in a tool-less manner. A sensor and control system for the plurality or removable pumps is also disclosed.