The present invention relates to a water dispenser system, and more particularly to an instant hot water dispenser system.
Water is one of the important constituents of the human body. For example, blood, lymph fluid and secretions of the human body are all related to water. Water accounts for about 70% of an adult's body weight. The water content in the blood is more than 90%. When we eat foods, digestion, transport of nutrients and waste excretion need the help of water to proceed smoothly. Water can lubricate joints and prevent eyeballs from drying out. Saliva and gastric juice can help digestion. Water also regulates body temperature, removing excess heat from the body through perspiration. Drinking more water can reduce uric acid and prevent gout, and it can also reduce the calcium concentration in the urine and avoid urinary tract stones. Therefore, the daily amount of water intake should be within the range of 2000-3000 cc.
However, the general domestic tap water mainly includes three stages, namely, collection, purification and water distribution. Although abnormalities in the water flowing to the home cannot be seen with the naked eye, the pollution gradually accumulates in these three stages. For the above reasons, some homes are equipped with boiling and filtering water dispensers. In general, water dispensers on the market usually use a hot water storage container and a heating device to provide high-temperature hot water. After the hot water in the water storage container is used up, the hot water cannot flow out of the water outlet. The water dispenser needs to refill with cold water in the water storage bucket and complete the boiling process before the water dispenser can provide hot water. This deficiency in the current system needs to be improved.
Accordingly, the inventor of the present invention has devoted himself based on his many years of practical experiences to solve these problems.
The primary object of the present invention is to provide an instant hot water dispenser system.
In order to achieve the aforesaid object, the instant hot water dispenser system, comprises a main body, a faucet, a first heating unit, a second heating unit, a plurality of temperature sensor, and a processing unit.
The main body has a water flow control valve seat, a water inlet and a water outlet. The water flow control valve seat is provided with a first flow control valve and a second flow control valve. One end of the water inlet is connected to a tap water pipeline. Another end of the water inlet is connected to a chamber of the water flow control valve seat. The chamber communicates with the first flow control valve and the second flow control valve. The second flow control valve communicates with a first water inlet of a water collection device. The water outlet communicates with the faucet through a water pipeline.
The faucet is provided with a first pull member, a second pull member and a water outlet pipe. The first pull member is configured to control a water supply sent from the tap water pipeline to the water outlet pipe. The second pull member is configured to control a water supply sent from the water outlet to the water outlet pipe.
The first heating unit has a first water storage space and a heater. One side of the first water storage space communicates with the first flow control valve. Another side of the first water storage space communicates with the second water inlet of the water collection device. The heater is configured to preheat a water supply in the first water storage space to a predetermined temperature.
The second heating unit has a circulating water path and an instantaneous heater. One side of the circulating water path communicates with a third water outlet of the water collection device. Another side of the circulating water path communicates with the water outlet of the main body. The instantaneous heater is configured to instantaneously heat a water supply in the circulating water path to a predetermined temperature.
The plurality of temperature sensors are respectively disposed on the water flow control valve seat, the first heating unit, the third water outlet of the water collection device and the water outlet of the main body for sensing temperatures of the water supplies and sending a signal of the temperatures of the water supplies to the processing unit.
The processing unit is electrically connected to a control interface and an external power source. The processing unit is further electrically connected to the water flow control valve seat, the first heating unit and the second heating unit.
Preferably, a water filtering device is provided between the water inlet of the main body and the tap water pipeline.
Preferably, the second pull member includes a safety switch. The safety switch is a spring rod. After the spring rod is pressed down, a bottom of the spring rod is engaged with an engaging hole so that the second pull member can be slightly rotated about an axis.
Preferably, the second pull member includes a micro switch. The micro switch is electrically connected to the processing unit. When the second pull member is slightly rotated to a predetermined position, the micro switch starts the processing unit.
Preferably, the first heating unit and the second heating unit further include a plurality of temperature protection switches.
Preferably, the control interface is provided with a water-dispensing button, a temperature button, a number button, a temperature display, a water volume display, and a status display of a water filtering device.
Preferably, when the processing unit receives a water-dispensing temperature signal from the control interface and determines that the water-dispensing temperature signal is less than 40° C., the second flow control valve is opened, and the water supply in the chamber is sent to the water outlet through the water collection device and the second heating unit.
Preferably, when the processing unit receives a water-dispensing temperature signal from the control interface and determines that the water-dispensing temperature signal is 40° C.-85° C., the second flow control valve and the second water inlet of the water collection device are opened, and the water supply in the chamber and the water supply in the first water storage space are mixed to meet the water-dispensing temperature signal through the water collection device and then sent to the water outlet.
Preferably, when the processing unit receives a water-dispensing temperature signal from the control interface and determines that the water-dispensing temperature signal is above 85° C., the second water inlet of the water collection device is opened, and the water supply in the first water storage space is sent through the water collection device to the circulating water path of the second heating unit for heating, when the temperature of the water supply reaches the water-dispensing temperature signal, the water supply is sent to the water outlet.
Referring to
The main body 10 has a water flow control valve seat 11, a water inlet 12, and a water outlet 13. The water flow control valve seat 11 is provided with a first flow control valve 111 and a second flow control valve 112. One end of the water inlet 12 is connected to a tap water pipeline through a water pipeline, and another end of the water inlet 12 is connected to a chamber 113 of the water flow control valve seat 11. The chamber 113 communicates with the first flow control valve 111 and the second flow control valve 112. The second flow control valve 112 communicates with a first water inlet 21 of a water collection device 20. The water outlet 13 communicates with the faucet 90 through the water pipeline. A water filtering device 70 is provided between the water inlet 12 of the main body 10 and the tap water pipeline.
The faucet 90 is provided with a first pull member 91, a second pull member 92, and a water outlet pipe 93. The first pull member 92 is configured to control the water supply sent from the tap water pipeline to the water outlet pipe 93. The second pull member 92 is configured to control the water supply sent from the water outlet 13 to the water outlet pipe 93.
The first heating unit 30 has a first water storage space 31 and a heater. One side of the first water storage space 31 communicates with the first flow control valve 111, and another side of the first water storage space 31 communicates with the second water inlet 22 of the water collection device 20. The heater is configured to preheat the water supply in the first water storage space 31 to a predetermined temperature (the preset value is 85° C.).
The second heating unit 40 has a circulating water path 41 and an instantaneous heater. One side of the circulating water path 41 communicates with a third water outlet 23 of the water collection device 20, and another other side of the circulating water path 41 communicates with the water outlet 13 of the main body 10. The instantaneous heater is configured to instantaneously heat the water supply in the circulating water path 41 to a predetermined temperature.
The first heating unit 30 and the second heating unit 40 further include a plurality of temperature protection switches 80. If the first heating unit 30 or the second heating unit 40 is abnormal and the water temperature exceeds a preset value (such as a temperature above 110° C.), the processing unit 50 immediately command the first heating unit 30 or the second heating unit 40 to stop heating.
The processing unit 50 is electrically connected to a control interface 51 and an external power source 52. The processing unit 50 is further electrically connected to the water flow control valve seat 11, the first heating unit 30 and the second heating unit 40. The control interface 51 is provided with a water-dispensing button, a temperature button, a number button, a temperature display, a water volume display, and a status display of the water filtering device 70.
The plurality of temperature sensors 60 are respectively disposed on the water flow control valve seat 11, the first heating unit 30, the third water outlet 23 of the water collection device 20 and the water outlet 13 of the main body 10 for sensing the temperatures of the water supplies and sending a signal of the temperatures of the water supplies to the processing unit 50.
Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings.
Referring to
When the user wants to drink drinking water (60° C.), first, the user presses the spring rod 9211 on the safety switch 921 to slightly rotate the second puller member 92 to a predetermined position and touches the micro switch 922 to start the processing unit 50. At this time, the user elects and presses the temperature button (60° C.) on the control interface 51. When the processing unit 50 receives the water-dispensing temperature signal from the control interface 51 and determines that the water-dispensing temperature signal is 60° C., the second flow control valve 112 and the second water inlet 22 of the water collection device 20 are opened to mix the water supply in the chamber 113 and the water supply in the first water storage space 31 through the water collection device 20 to be at a temperature of 60° C. Finally, the water supply flows from the water outlet 13 to the water outlet pipe 93 of the faucet 90 through the water outlet pipe, so as to supply drinking water (40° C.) immediately.
When the user wants to drink drinking water (95° C.), first, the user presses the spring rod 9211 on the safety switch 921 to slightly rotate the second puller member 92 to a predetermined position and touches the micro switch 922 to start the processing unit 50. At this time, the user elects and presses the temperature button (95° C.) on the control interface 51. When the processing unit 50 receives the water-dispensing temperature signal from the control interface 51 and determines that the water-dispensing temperature signal is 95° C., the second water inlet 22 of the water collection device 20 is opened, and the water supply in the first water storage space 31 is sent to the circulating water path 41 of the second heating unit 40 via the water collection device 20 for heating. When the temperature of the water supply reaches 95° C., the water supply flows from the water outlet 13 to the water outlet pipe 93 of the faucet 90 via the water outlet pipe, so as to supply drinking water (95° C.) immediately.
The instant hot water dispenser system of the present invention has the following advantages:
1. The water supply with a medium-high temperature in the first water storage space 31 is sent to the circulating water path 41 of the second heating unit 40 for heating instantaneously. The water supply can be effectively heated to a specified high temperature in a short time.
2. Since the water supply in the first water storage space 31 is maintained at a medium-high temperature at any time, it can be continuously replenished to the circulating water path 41, and hot water above 95° C. is not easily consumed.
Although particular embodiments of the present invention have been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the present invention. Accordingly, the present invention is not to be limited except as by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
107217063 | Dec 2018 | TW | national |