This invention is a refrigeration, dispensing, and management system for beverage and beverage containers that includes a tap attached to an upper door and a supply line; a recess base in a recess of a housing; a slide slidably carried by the recess base having a slot; a pressurized gas cylinder connected to the housing and attached to a gas line in fluid communications with the supply line wherein the gas cylinder contains gas selected from the group consisting of O.sub.2, CO.sub.2, N.sub.2 or other inert gas; and, a cap placed on the beverage container so that when the tap is opened, pressurized gas enters the cap and the snorkel through an inlet defined in the cap, forces gas into the beverage container, and forces the beverage out of the outline defined in the cap, through the supply line and out of the tap.

A beverage machine includes a valve that receives a base fluid and dispenses a mixed beverage comprising the base fluid and an additive fluid. The valve has a bore through which the base fluid flows, and the bore has a perimetral surface that defines a plurality of ports through which the additive fluid is injected to thereby mix with the base fluid. An injector is coupled to the valve and configured to radially inject the additive fluid into the base fluid through the plurality of ports as the base fluid flows through the bore such that the additive fluid mixes into the base fluid to form the mixed beverage.

A hand-held beverage dispenser includes a handle body, within which multiple valve units are contained. Two sets of fluid flow paths are provided into the handle body. The sets of fluid flow paths are mutually exclusive one to the other. Each flow path of the first set is in fluid communication with each valve unit, whereas only a predetermined one of the second set of fluid flow paths is in fluid communication with each valve unit. Each valve unit includes a flow control valve and a selection valve. The selection valve determines on an ad hoc basis which of the first set of flow paths will be utilized at any given time, while the flow control valve provides single action simultaneous ON-OFF control of fluid flows through both the selected flow path and the predetermined flow path.

A double-seat valve includes a housing having a passage between first and second connections. First and second valve disks are arranged in a housing internal space. A leakage space formed in the passage in the valve closed position is sealed off by the second valve disk. A hollow rod connected to the first valve disk has a leakage channel connecting the leakage space and a housing part. A cleaning gap is formed between the second valve disk and a passage wall. A housing opening is sealed with a diaphragm that separates the housing part from the internal space. A section of the first valve disk is received in an opening contour in the passage in the valve closed position, and delimits a cut-out in the first valve disk, in which the second valve disk is received in the valve open position.

A flow sensor includes a fluid chamber configured to receive a fluid. A diaphragm assembly is configured to be displaced whenever the fluid within the fluid chamber is displaced. A transducer assembly is configured to monitor the displacement of the diaphragm assembly and generate a signal based, at least in part, upon the quantity of fluid displaced within the fluid chamber.

A system for mixing a liquid beverage (e.g., a beer) from multiple liquid ingredients and dispensing the liquid beverage includes: a mixing chamber having an inlet valve and an outlet valve; a pump for drawing liquid into the mixing chamber through the inlet value; a manifold in fluid communication with the inlet valve of the mixing chamber and a source of each of the liquid ingredients (e.g., a keg); a tap associated with the mixing chamber for dispensing the liquid beverage mixed in the mixing chamber; and an electronic control module in communication with the pump, the electronic control module being programmed to cause the pump to sequentially draw a predetermined volume of more than one of the liquid ingredients into the mixing chamber, the predetermined volumes corresponding to a recipe for the liquid beverage.

Examples herein relate generally to reservoirs for use in water distribution systems within an appliance. The reservoir herein allows for the combination of various components prepared by separate manufacturing processes and for reducing waste of those manufacturing components. Specifically, the reservoir herein provides a daisy-chain structure for forming a ganged reservoir system.

A smart energy-saving device for automatic blending drinks, adopted to inject beverages into at least one beverage cup that comprises a bar code, comprises: beverage barrels; manifolds; at least one ice-storing device including at least one ice outlet, at least one servomotor, a stirring rod, and at least one thruster; beverage stations; collection mechanisms including ring structures, ice inlets, water inlets, and beverage tubes; and a control module including flowmeters, water valve switches, beverage-cup-weight sensors, beverage-barrel-weight sensors, at least one ice-beverage-barrel-weight sensor, pressure sensors, bar code readers, infrared scanners; and a controller.

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 hand-held beverage dispenser includes a handle body, within which multiple valve units are contained. Two sets of fluid flow paths are provided into the handle body. The sets of fluid flow paths are mutually exclusive one to the other. Each flow path of the first set is in fluid communication with each valve unit, whereas only a predetermined one of the second set of fluid flow paths is in fluid communication with each valve unit. Each valve unit includes a flow control valve and a selection valve. The selection valve determines on an ad hoc basis which of the first set of flow paths will be utilized at any given time, while the flow control valve provides single action simultaneous ON-OFF control of fluid flows through both the selected flow path and the predetermined flow path.