The water-dispensing system for furniture further includes a plurality of vessel structures. Each of the plurality of vessel structures is a mechanical structure that contains the water in preparation for consumption. The plurality of vessel structures automatically refills the water after the water has been consumed.

The vehicular water-dispensing method incorporates a water recovery process, a water STT process, and a discharge process. The water recovery process: a) converts water contained in a gas phase in the atmosphere into water in a liquid phase; b) initially treats the converted liquid phase water to remove microorganisms and other chemical contaminations; and c) transports the initially treated liquid phase water to the water STT process. The water STT process: a) receives and stores the initially treated (liquid phase) water from the water recovery process; b) subsequently treats the stored water with a final treatment to remove microorganisms and other chemical contaminations; and, c) transports the treated stored water to the discharge process. The discharge process: a) receives the water from the water STT process after the final treatment; and, b) controls the discharge of the water received from the water

The system (10) for the transfer of fluid comprises a tubular fluid transfer line (2) comprising at one of its ends a coupling system (32) adapted to be connected to a target duct (33) for the transfer of fluid, and electrical actuators (11-13) for controlling the movement of the transfer line in space, each via an actuating shaft, characterized in that each of the actuators for controlling the movement of the transfer line comprises an electric motor with an output shaft, a speed reducer, the actuating shaft being rotationally driven by the motor output shaft by means of the speed reducer, which is reversible, so as to enable the actuating shaft to turn when an actuating torque is directly applied to it, and braking means for locking the actuator in position when movement control is in course and that actuator is not activated for that control.

The present invention relates to a beverage dispensing system (10) comprising a beverage dispensing region (2) for a drinking establishment, said beverage dispensing region (12) including a plurality of beverage containers (20a, 20b, 20c, 22a, 22b, 22c) and one or more tapping heads (34) for dispensing beverage, the one or more tapping heads (34) having a beverage dispensing control means and a spout for dispensing beverage into a beverage recipient, wherein each of said plurality of beverage containers includes a beverage outlet in communication with said beverage, in which the beverage dispensing system further comprises a remote control means (16) being connected to a valve (18), said valve (18) being connected to a plurality of said beverage outlets for switching the dispensing of beverage from a first beverage container to a second beverage container and wherein said remote control means (16) and said valve (18) are located in the near vicinity of said one or more tapping heads (34).

Among other things, beverages are dispensed from one or more beverage dispensers based on selections made by users. Information about the dispensing of the beverages is sent to a central server where it is used to manage a variety of functions including replacement of depleted supplies of components. Various features of the beverage dispensers enable the beverages that are dispensed to be uniform and appealing to users.

The vehicular water-dispensing system is an enhancement to non-provisional application U.S. Ser. No. 16/695,416. Application U.S. Ser. No. 16/695,416 comprises a first retractable hose and a second retractable hose. The vehicular water-dispensing system comprises a logic module, a solenoid valve, a flow meter, and a plurality of vessel structures The logic module, the solenoid valve, and the flow meter controls the flow of drinking water into the plurality of vessel structures. The flow meter measures the flow of drinking water discharged from the solenoid valve. The logic module, the solenoid valve, and the flow meter are electrically connected to form a feedback loop that controls the flow of drinking water through the solenoid valve. Each of the plurality of vessel structures is a mechanical structure that contains the drinking water in preparation for consumption. The plurality of vessel structures automatically refills the drinking water after the drinking water has been consumed.

A liquid dispenser, such as a water purifier, in one embodiment includes a water discharger connector provided with a water discharge valve configured to control discharge of purified water and a water discharge pipe connected to the water discharge valve, and a water discharger coupled to an upper side of the water discharger connector, and provided with a connector part that connects to the water discharge pipe based on fitted-coupling.

A removable reservoir water dispensing system which includes a water dispenser body with a built-in water reservoir and a coupling for connecting a removable water reservoir to the built-in reservoir. A drainage pipe, through which water is drained from the built-in reservoir, extends through a bottom of the built-in reservoir. The drainage pipe has a first end and a second end. The second end is connected to a dispensing faucet on the water dispenser body. The first end extends vertically into the built-in water reservoir for at least one third of a height of the built-in water reservoir. Water in the built-in water reservoir, positioned below the first end of the drainage pipe, is unable to pass through the drainage pipe to the dispensing faucet and is always resident in the built-in water reservoir at a pre-set dispensing temperature.

A water purifier that includes: a filter unit that is configured to purify water; a cooling unit that is configured to cool water purified by the filter unit using cooling water; a water discharge unit that is configured to discharge water cooled by the cooling unit; a cold water flow path that couples the cooling unit to the water discharge unit and through which water cooled by the cooling unit passes; a cold water discharge valve that is coupled to a first side of the cooling unit and that is configured to control water flow inside the cold water flow path; and a check fitting unit that is coupled to a first side of the water discharge unit and that is configured to block pressure change inside the cold water flow path is disclosed.

A drink station is provided with an alkaline filter cartridge in fluid communication with an ambient temperature water line provide alkaline water, and with a chilled water mixed with the alkaline water at a spigot to provide chilled alkaline water. A hot water heating element is located below the spigot so hot water flows upward for dispensing from the spigot, with a vent line between the heating element and spigot helping hot water to flow from the spigot to the heating element. A refrigeration system and a carbonation system is also provided. The refrigeration system uses the ice-bank technology. A submersible agitator pump improves heat exchanged between ice-bank and water by forced convection. The agitator pump operating based on the temperature of the drinking water. A figure eight evaporator coil can provide two cylindrical ice banks and two chilled water coils to increase the chilled water capacity.