The present disclosure relates to liquid dispensing arrangements, and particularly to arrangements for distribution of a dispensed liquid.

Provided are a water dispensing apparatus and a control method of the water dispensing apparatus. The water dispensing apparatus includes a main body, and an infrared sensing device. The infrared sensing device includes a mounting support, an electric control board having an infrared transmitting device and an infrared receiving device. The infrared receiving device is configured to receive an infrared ray transmitted by the infrared transmitting device. The mounting support has a first through hole at a position corresponding to the infrared transmitting device, and a second through hole at a position corresponding to the infrared receiving device.

A water purifier includes a water tank having a cold water path inside the tank, a coolant inside the water tank, a cooling device including an evaporator inside the water tank and through which a refrigerant flows, and a compressor that is operable to compress the refrigerant. The cooling device is configured to cool the coolant to cool water flowing through a temperature sensor, which is configured to detect a temperature of the coolant and output coolant temperature information about the detected temperature of the coolant. The purifier also includes an agitator operable to agitate the coolant and a controller configured to control the compressor and the agitator to operate simultaneously and control the agitator to stop operating while the compressor is controlled to continue operating based on preset ice-making temperature information and the coolant temperature information. There is also a method of controlling a compressor and an agitator.

The apparatus includes a reservoir (2), a liquid source (1), a carbon dioxide source (12), a non-return valve (8), a carbonating vessel (7) to receive liquid from the reservoir (2) via the non-return valve (8), a gas inlet (15) to receive carbon dioxide from the carbon dioxide source (12), and a dip tube (16) to withdraw carbonated liquid from the carbonating vessel. A pressure relief valve (20) vents gas from the carbonating vessel (7), and a dispense valve (18) controls the supply of carbonated liquid from the dip tube (16) to a dispense outlet (17). A charge control valve (14) controls the supply of carbon dioxide to the carbonating vessel (7). The apparatus has the following modes of operation-charge: the dispense valve (18) is held closed while the charge control valve (14) is opened to admit a charge of carbon dioxide into the carbonating vessel (7); dispense/refill: the dispense valve (18) is opened to dispense carbonated liquid while liquid flows into the carbonating vessel from the reservoir (2) via the non-return valve (8). The carbonated beverage can

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A water ejecting apparatus includes a case and a water ejection unit connected to one side of the case. The water ejection unit includes a fixed cover, a lifting cover, a lifting motor, a water ejection nozzle, a touch bar, a detection sensor, and a controller. The fixed cover is connected to the case. The lifting cover is movably received in the fixed cover and coupled to the lifting motor. The water ejection nozzle is installed at a lower end of the lifting cover and configured to eject water. The touch bar is at least partially received in the lifting cover and moves when in contact with a container placed below the water ejection nozzle. The detection sensor detects movement of the touch bar. The controller changes operation of the lifting motor when the detection sensor detects movement of the touch bar.

A water ejecting apparatus includes a case and a water ejection unit connected to the case. The water ejection unit includes a fixed cover connected to the case, having atop dead point and a bottom dead point, and including a lifting gear provided between the top dead point and the bottom dead point, a lifting cover movably coupled to the fixed cover, a lifting motor coupled to the lifting cover and a gear module interworking with the lifting motor and the lifting gear, a water ejection nozzle for ejecting water, a signal detecting unit that detects a frequency generation (FG) signal generated by the lifting motor during an operation of the lifting motor, and a controller configured to control the operation of the lifting motor upon determining that the lifting cover reaches the top dead point or the bottom dead point based on the FG signal.

A stirrer includes a stirring shaft; a plurality of mixing wings extending from the lower end of the stirring shaft and spaced from each other around the stirring shaft; and a conical hub connecting the lower ends of the mixing wings.

Disclosed is a hot water discharging apparatus. A hot water discharging apparatus according to an embodiment of the present invention comprises: a water heater for heating water that has flowed into hot water, and discharging the hot water; and a hot water discharge unit that is connected to the water heater so that the hot water discharged from the water heater is discharged to the outside, wherein the water heater is provided with an outlet through which the hot water is discharged, the hot water discharge unit includes a hot water discharge member connected to the outside so that the hot water is discharged to the outside, and the water heater may be disposed so that the outlet is located higher than the hot water discharge-side end of the hot water discharge member.

A water purifier includes a raw water flow path into which raw water is introduced, a clean water flow path connected to the raw water flow path and having a water discharge nozzle disposed at an end, a filter device disposed in the clean water flow path, and to which a filter is installable to filter the raw water, a drain flow path branched off from the clean water flow path between the filter and the water discharge nozzle and connected to a drain port to drain water in the clean water flow path to outside, a drain valve configured to open or close the drain flow path, and a controller configured to determine a remaining life of the filter on a point in time at which the filter has been replaced and control the drain valve to perform a cleaning operation based on the remaining life of the filter.

The present invention relates to a multi-purpose hydration station for dispensing different kinds of beverages, soft ice, ice, hot water and non-heated water. More specifically, the multi-purpose hydration station features a hot water dispenser unit, a non-heated water dispenser unit, a beverage dispenser unit, a soft ice dispenser unit and an ice maker for dispensing the user's requested item and eliminates the need to use separate dispensing machines to dispense different kinds of beverages or items. Additionally, the hydration station features a refrigeration and a non-refrigeration storage area to allow the users to store their items as per their requirements. The hydration station offers a convenient solution for setting up a hydration station that saves space, energy and expenses of the user.