Disclosed is a water dispenser. The water dispenser includes a water outlet component; a water cooling module for accessing a water source, an output port of the water cooling module being communicated with the water outlet component through a first water pump; and/or a water heating module, an input port of the water heating module accessing the water source through a second water pump, an output port of the water heating module being communicated with the water outlet component, the water outlet component accessing the water source through the second water pump.

Disclosed is a water dispenser. The water dispenser includes a water outlet component; a water cooling module for accessing a water source, an output port of the water cooling module being communicated with the water outlet component through a first water pump; and/or a water heating module, an input port of the water heating module accessing the water source through a second water pump, an output port of the water heating module being communicated with the water outlet component, the water outlet component accessing the water source through the second water pump.

A water output device is provided. The water output device comprises a housing mechanism; a water purification mechanism, which comprises a water purifier located within the housing mechanism; a refrigeration mechanism, which comprises a compressor located within the housing mechanism; a tank assembly, which comprises a first tank mechanism configured for providing hot water, and second tank mechanism configured for providing ice water and soda water; the first tank mechanism comprises a hot water tank in communication with the water purifier; the second tank mechanism comprises a ice water tank in communication with the water purifier, a soda water tank located within the ice water tank, a water pump in communication with the ice water tank and the soda water tank respectively, and a cooling pipe spirally extended into the ice water tank.

A dispenser head for in-line mixing and dispensing of beverages, which may be carbonated or nitrogenated. The dispenser head comprising a pump, a dilution mechanism, an additive mechanism, and outlet nozzle and optionally a regulation system. In use, the pump can pump concentrate liquid for the liquid product from a concentrate source to the dilution mechanism; the dilution mechanism can receive diluent liquid suitable for the liquid product from a diluent source, operable to mix the diluent liquid and the concentrate liquid and provide diluted concentrate liquid; and the additive mechanism can receive additive fluid for the liquid product from an additive source, to combine the diluted concentrate liquid and the additive fluid. The regulation system comprises a pump regulator means for regulating the quantity of concentrate liquid pumped into the dilution mechanism within the dispense period; a diluent quantity regulator means for regulating the flow of diluent liquid into the dilution mechanism; and an additive quantity regulator means for regulating the flow of additive fluid into the additive mechanism. Preferably, the dispenser head is a unitary device, which may be supplied attached to a vessel containing the concentrate.

A method and computer program product for defining a PWM drive signal having a defined voltage potential. The PWM drive signal has a plurality of “on” portions and a plurality of “off” portions that define a first duty cycle for regulating, at least in part, a flow rate of a pump assembly. At least a portion of the “on” portions of the PWM drive signal are pulse width modulated to define a second duty cycle for the at least a portion of the “on” portions of the PWM drive signal. The second duty cycle regulates, at least in part, the percentage of the defined voltage potential applied to the pump assembly.

A method and computer program product for defining a PWM drive signal having a defined voltage potential. The PWM drive signal has a plurality of “on” portions and a plurality of “off” portions that define a first duty cycle for regulating, at least in part, a flow rate of a pump assembly. At least a portion of the “on” portions of the PWM drive signal are pulse width modulated to define a second duty cycle for the at least a portion of the “on” portions of the PWM drive signal. The second duty cycle regulates, at least in part, the percentage of the defined voltage potential applied to the pump assembly.

A smart inventory management system is described for a dispensing and blend-in-cup beverage platform including a container having an information tag that is configured to store unique information specific to a particular product, a reader configured to read the stored information from the information tag, a control board configured to host a software based decision engine which is configured to interpret the information specific to a particular product and to control one or more system components based at least in part on the information, a pump controlled by the control board and configured to pump beverage concentrates out of the containers in order to dispense the beverage concentrate into a beverage holder, and a check valve located between an opening on the container and the pump, the check valve configured to provide backflush prevention of foreign solutions into the container.

A smart inventory management system is described for a dispensing and blend-in-cup beverage platform including a container having an information tag that is configured to store unique information specific to a particular product, a reader configured to read the stored information from the information tag, a control board configured to host a software based decision engine which is configured to interpret the information specific to a particular product and to control one or more system components based at least in part on the information, a pump controlled by the control board and configured to pump beverage concentrates out of the containers in order to dispense the beverage concentrate into a beverage holder, and a check valve located between an opening on the container and the pump, the check valve configured to provide backflush prevention of foreign solutions into the container.

A system includes a sensor and a computing system. The sensor is coupled to a syrup line of the beverage dispenser and is configured to measure a pressure within the line. The syrup line is coupled at a first end to a syrup bag and at a second end to a pump configured to pump syrup from the syrup bag to an outlet of the beverage dispenser. The pump is operated using pressurized gas and generates a pressure corresponding to the pressure of the gas within the syrup line when both the syrup bag is full and the outlet of the beverage dispenser is closed. The sensor transmits a measured pressure to the computing system. The computing system determines that the measured pressure is less than a threshold pressure. In response, the processor transmits an alert for display on a user device, which identifies the syrup bag for replacement.

The present application provides a nutating pump assembly for pumping a fluid. The nutating pump assembly may include a nutating pump and an air vent chamber assembly in fluid communication with the nutating pump.