A method for water temperature stepless adjustment of pipeline water dispenser includes connecting a water inlet pipe, a heat exchanging sump, a heating sump, a heat exchanger, a refrigeration sump, and a water outlet pipe, in turn, to form water inlet and outlet pipelines of a water dispenser; configuring a plurality of motorized valves or magnetic valves; configuring a plurality of temperature sensors; configuring a PLC control system which is connected with the motorized valves or magnetic valves, the temperature sensors, the heating sump, the refrigeration sump; setting outlet water temperature and water capacity and controlling the motorized valves or magnetic valves, and the temperature sensors; and controlling the PLC control system to calculate and judge to supply water with desired temperature and desired capacity.

A beverage supply apparatus includes cooling device 6, milk tank 5 in storage chamber 6a of cooling device 6, and detection device 7 that detects the milk. Detection device 7 has first light guide body 7c to penetrate partition wall 12 having a multilayer box body that partitions storage chamber 6a, second light guide body 7d to penetrate partition wall 12 which faces first light guide body 7c, light projection unit 7a attached to partition-wall outer-surface-side end of first light guide body 7c to project light via the body 7c, and light receiving unit 7b attached to the partition-wall outer-surface-side end of second light guide body 7d to receive light transmitted through milk tank 5 via second light guide body 7d. The detection device detects the presence or absence of or the remaining amount of milk based on a light reception state in the light receiving unit 7b.

A water dispenser and a method of controlling a water dispenser are provided. The water dispenser may control power output of an induction heater having a hot water module based on changes in flow rate of water supplied or a temperature of water discharged.

A liquid dispenser is provided. The liquid dispenser may include a water tank to store water, a cooling module provided in the water tank to circulate cooling water to cool the water to make cold water, a drain valve that connects to the water tank and protrudes from the water tank to discharge the cooling water in the water tank, and a foam insulator that covers an outer circumferential surface of the water tank and contacts the drain valve to prevent the drain valve from being exposed to air.

A networked system for providing and maintaining a set of liquid dispenser stations is described. The fluid dispensers communicate with a managing/supervisory cloud server via an interposed base station. The fluid dispensers communicate locally with the base station via wireless communication network links. The base station operates as an accumulator of status/usage information provided by the dispenser stations and bridge for passing information and control commands between the cloud server and the individual dispenser stations. The dispenser stations are configured with control processors (controllers) to facilitate performing a variety of local control operations associated with dispensing liquids that have been cooled (or heated) prior to dispensing by the dispenser stations. Additionally, the dispenser stations cooperatively operate with the cloud server (via the base station) to support a variety of real time control and maintenance operations relating to the dispenser stations operating at potentially thousands of distinct geographic locations.

A method for water temperature stepless adjustment of pipeline water dispenser includes connecting a water inlet pipe, a heat exchanging sump, a heating sump, a heat exchanger, a refrigeration sump, and a water outlet pipe, in turn, to form water inlet and outlet pipelines of a water dispenser; configuring a plurality of motorized valves or magnetic valves; configuring a plurality of temperature sensors; configuring a PLC control system which is connected with the motorized valves or magnetic valves, the temperature sensors, the heating sump, the refrigeration sump; setting outlet water temperature and water capacity and controlling the motorized valves or magnetic valves, and the temperature sensors; and controlling the PLC control system to calculate and judge to supply water with desired temperature and desired capacity.

The present invention discloses a beverage dispenser, including: an inlet connected to a water source; an outlet for dispensing the water to a user vessel; at least one filter element having an input and an output for filtered water; a pump for pumping water to the input of the filter element; a flow sensor connected between the inlet and the outlet, wherein the flow sensor determines the actual flow rate of the water; at least one water preparation element connected between the output for outputting filtered water and the outlet and adapted to prepare the water for drinking by a human, wherein the water preparation element comprises a water preparation rate input by which the water preparation rate of the water preparation element can be controlled; and a controller connected to the water preparation rate input of the water preparation element and the flow sensor, wherein the controller controls the water preparation rate of the water preparation element by a signal to the water preparation rate input such that the water preparation rate is proportional to the actual flow rate.

The present invention discloses a beverage dispenser, including: an inlet connected to a water source; an outlet for dispensing the water to a user vessel; at least one filter element having an input and an output for filtered water; a pump for pumping water to the input of the filter element; a flow sensor connected between the inlet and the outlet, wherein the flow sensor determines the actual flow rate of the water; at least one water preparation element connected between the output for outputting filtered water and the outlet and adapted to prepare the water for drinking by a human, wherein the water preparation element comprises a water preparation rate input by which the water preparation rate of the water preparation element can be controlled; and a controller connected to the water preparation rate input of the water preparation element and the flow sensor, wherein the controller controls the water preparation rate of the water preparation element by a signal to the water preparation rate input such that the water preparation rate is proportional to the actual flow rate.

A refrigerator appliance having a quick fill dispenser to rapidly fill a container. The refrigerator may include a water storage receptacle. The water storage receptacle may be in fluid communication with a water filter. The water storage receptacle may dispense water at a flow rate greater than the flow rate entering the water storage receptacle. A valve may be downstream of the water storage receptacle.

A water dispenser and a method of controlling a water dispenser are provided. The water dispenser may control power output of an induction heater having a hot water module based on changes in flow rate of water supplied or a temperature of water discharged.