A beverage dispenser includes a source of a base fluid, a source of a concentrate, and an assembly configured to receive and dispense the base fluid and the concentrate together as a mixed beverage having a predetermined base fluid-to-concentrate ratio. An actuator is configured to control flow of the base fluid and the concentrate to the assembly. The assembly is configured to premix a first portion of the base fluid with the concentrate to form a premixed concentrate, and to then dispense a combination of the premixed concentrate and a second portion of the base fluid as the mixed beverage having the predetermined base fluid-to-concentrate ratio. The actuation of the actuator causes an uninterrupted dispense of the base fluid and the concentrate from the source of the base fluid and the source of the concentrate, respectively, to the assembly, and from the assembly to a consumer of the mixed beverage.

The present system generally relates to a fluid flow system where a controller and motor pump assemblies are used to optimize the control of fluid flow through the system. The controller samples the back electromotive force of the motor and pump assemblies and is able to utilize the sampled back electromotive force in conjunction with predefined target back electromotive force values, preferably empirically determined and tuned to an individual motor and for a select fluid, to tune the voltage applied to the system, control the back electromotive force of the system and, by extension, control the flow of fluid.

A liquid dispenser may include a container having an upper opening, a pump provided in the container, a pipe through which liquid discharged from the pump is transferred, a top plate having an upper surface over which liquid flows, a filter assembly provided below the top plate, a base provided below the container, and a thermoelectric element provided in the base to cool the liquid in the container.

A dispense control system for a dispensing assembly of a refrigerator appliance and a method for operating the same are provided. The dispensing assembly defines a base plane for receiving a container. A dispense control system includes an emitter for directing a beam of energy toward the container and the base plane and a receiver for detecting a projection of the beam of energy in an image plane of the receiver. The dispense control system may be configured to obtain a measured displacement of the projection when the container is positioned on the base plane, and an actual height of the container or a liquid level within the container may be determined from the measured displacement of the projection.

A touch-free flowable food product dispenser is disclosed. The food product dispenser includes a main body, a pump assembly mounted in the main body and a cover member mounted to the main body. The cover member is part of an automated pump actuation unit that can be removably mounted to the main body such that the automated pump actuation unit engages a pump assembly supported by the main body. The automated pump actuation unit includes a sensor positioned to detect the presence of an actuation member, such as a hand, in proximity to the sensor. When the actuation member is detected, the automated pump actuation unit actuate the pump assembly to dispense the food product. The cover member and automated pump actuation assembly are formed as a single unit that can be installed on the main body to convert manual pump dispensers to touch-free dispensers.

A flow diverting device is provided at the lower end of the dip-tube (D) in a bag-in-keg container (C) which is filled top-side-down, e.g. with beer. The device directs the incoming flow to run smoothly back down the outside of the dip tube, gently into the already pooled beer thus minimising any fountain effect and associated turbulence. The device can also be used with single-wall metal or plastic kegs to reduce the dispensing of sediment and allow a greater volume of beer to be withdrawn without fobbing.

A water purifier according to an embodiment of the present invention may include a housing accommodating components for generating cold water and/or hot water; a water cock which protrudes from a front surface of the housing, the water cock being configured to discharge the cold water or the hot water; a control panel which is provided so as to input a command for discharging the cold water or the hot water; a sterilization module which is detachably mounted on the water cock, the sterilization module being configured to emit ultraviolet rays for sterilizing the inside of the water cock; and a fastening part which is formed on the water cock and the sterilization module, respectively, so that the sterilization module can be attached to and detached from the water cock.

A system for automatically dispensing beverages according to a drink order. The system includes a conveyor that conveys a plurality of cup holders in and between a cup receiving location, a dispensing location, and a serving location. A cup dispenser is configured to dispense a cup into each of the plurality of cup holders at the cup receiving location. A plurality of additive dispensers is configured to dispense additives to the cup at the dispensing location. A controller is configured to receive the drink order, create a recipe from the drink order and link the recipe with one of the plurality of cup holders via a marker, dispense a cup to the cup holder via the cup dispenser, and thereafter control the conveyor and the plurality of additive dispensers so that the cup is filled with a beverage according to the recipe and then conveyed to the serving location.

The present invention provides a method for controlling a drinking-water supply device, the method comprising: a first step of connecting a guide pipe of a case separable from a cabinet to form a channel through which water moves from the case to the cabinet; a second step of supplying the cabinet with sterile water electrolyzed by an electrolytic module included in the case; and a third step of supplying the cabinet with water which has not passed through the electrolytic module included in the case, wherein the sterilization water and the water are supplied to the cabinet from the case via the guide pipe in the second step and the third step.

A water inlet pipe connects a water supply to a faucet. A water flow control valve in the water inlet pipe regulates the flow of water through the water inlet pipe from the water supply to the faucet. A drip tray located beneath the faucet captures water overflow. A conduit connects the drip tray a storage container such that water in the drip tray drains into the storage container. A water level sensor associated with the storage container generates a overflow signal when the water level in the storage container reaches a pre-set level. The water flow control valve automatically prevents water flow through the water inlet pipe to the faucet in response to the overflow signal. A visible display and a sound generator are also energized in response to the alarm signal.