CN219693572U - System capable of realizing warm boiled water - Google Patents

Abstract

The utility model discloses a system capable of realizing warm boiled water, which comprises a water inlet, a water storage module, a heating module, a cooling module and a pure water outlet, wherein the water inlet, the water storage module, the heating module, the cooling module and the pure water outlet are sequentially communicated through pipelines; the cooling module is arranged in the water storage module to exchange heat with boiled water in the cooling module through pure water in the water storage module, so that the boiled water in the heating module is cooled, thereby obtaining warm boiled water, no electric drive is needed, the structure is simple, the cooling energy consumption is reduced, the cooling effect is improved, and the energy waste is not easy to cause.

Description

System capable of realizing warm boiled water

[ field of technology ]

The utility model relates to the technical field of daily water treatment equipment, in particular to a system capable of realizing warm boiled water.

[ background Art ]

In the boiled water system of the existing tap water purifying device, when warm boiled water is needed, the heated boiled water is cooled, but the existing refrigerating equipment is mostly driven by electricity, when the boiled water is cooled, the cooling energy consumption is high, the cooling effect is poor, and the energy waste is easy to cause.

[ utility model ]

In order to solve the problems of high cooling energy consumption, poor cooling effect and serious energy waste when the tap water purifying device cools boiled water to obtain warm boiled water, the utility model provides a system capable of realizing warm boiled water.

The utility model is realized by the following technical scheme:

the utility model provides a can realize system of warm boiled water, includes the water inlet that communicates in proper order through the pipeline, water storage module, heating module, cooling module to and pure water delivery port, pure water delivery port respectively with water storage module heating module cooling module intercommunication supplies pure water delivery port exports warm water, hot water and warm boiled water in proper order, cooling module locates in the water storage module in order to pass through pure water in the water storage module is right cooling module carries out the cooling down.

The cooling module comprises a primary cooling device, a secondary cooling device and a flow dividing device arranged between the primary cooling device and the secondary cooling device;

the heating module is sequentially communicated with the primary cooling device, the flow dividing device and the pure water outlet to form a first cooling waterway;

the heating module is sequentially communicated with the primary cooling device, the flow dividing device, the secondary cooling device and the pure water outlet to form a second cooling waterway.

The system capable of realizing warm boiled water comprises the water storage module, the water inlet valve arranged on the water storage module and the UV disinfection lamp.

The system capable of realizing warm boiled water comprises the water inlet valve, the water inlet valve comprises a first liquid level switch, the first liquid level switch comprises a double-floating-ball liquid level switch, the double-floating-ball liquid level switch comprises an upper floating ball and a lower floating ball,

when the liquid level in the pure water tank is higher than the upper floating ball, triggering the first liquid level switch to close water inlet;

when the liquid level in the pure water tank is lower than the lower floating ball, the first liquid level switch is triggered to open water inflow.

The system for realizing warm boiled water comprises the water inlet valve and a standby mechanical valve.

The heating module comprises a vacuum tank, a second liquid level switch arranged in the vacuum tank, a heating pipe and a temperature sensor.

The system capable of realizing warm boiled water comprises the second liquid level switch, wherein the second liquid level switch comprises the floating ball liquid level switch, the floating ball liquid level switch is provided with the floating ball, the connecting pipeline between the water storage module and the heating module is provided with the water drain valve, and when the liquid level in the vacuum tank is lower than that of the floating ball, the second liquid level switch triggers the water drain valve to open so that pure water in the water storage module flows into the vacuum tank.

The system capable of realizing warm boiled water is characterized in that the cooling module is a water cooling coil pipe, and the water cooling coil pipe is used for exchanging heat with pure water in the water storage module so as to cool boiled water flowing out of the heating module.

According to the system capable of realizing warm boiled water, the exhaust pipe for exhausting the heating module is arranged between the water storage module and the heating module.

The system capable of realizing warm boiled water is characterized in that a filtering module is further arranged between the water inlet and the water storage module, and a waste water outlet and a waste water electromagnetic valve are arranged on the filtering module.

Compared with the prior art, the utility model has the following advantages:

the utility model provides a system capable of realizing warm boiled water, which is characterized in that a pure water outlet is respectively communicated with a water storage module, a heating module and a cooling module to supply the pure water outlet to sequentially output warm water, hot water and warm boiled water, the cooling module is arranged in the water storage module to exchange heat between the pure water in the water storage module and the boiled water in the cooling module so as to cool the boiled water in the heating module, thereby obtaining the warm boiled water without electric drive.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below.

FIG. 1 is a schematic diagram of a first embodiment of a structural connection of the present utility model;

FIG. 2 is a schematic diagram showing a first embodiment of the present utility model;

fig. 3 is a schematic structural connection diagram of a second embodiment of the present utility model.

[ detailed description ] of the utility model

In order to make the technical problems, technical schemes and beneficial effects solved by the utility model more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

A system capable of realizing warm boiled water as shown in fig. 1 to 2 includes a water inlet 1, a water storage module 3, a heating module 4, a cooling module 5 and a pure water outlet 6 which are sequentially communicated through pipelines, wherein the pure water outlet 6 is respectively communicated with the water storage module 3, the heating module 4 and the cooling module 5 so that the pure water outlet 6 sequentially outputs warm water, hot water and warm boiled water, and the cooling module 5 is arranged in the water storage module 3 so as to cool down the cooling module 5 through pure water in the water storage module 3; through pure water in the water storage module 3 and the boiled water in the cooling module 5 are subjected to heat exchange, so that the boiled water in the heating module 4 is cooled, thereby obtaining warm boiled water, no electric drive is needed, the structure is simple, the cooling energy consumption is reduced, the cooling effect is improved, and the energy waste is not easy to cause.

Further, the water storage module 3 includes a pure water tank 31, a water inlet valve 32 provided on the pure water tank 31, and a UV sterilizing lamp 33; the UV sterilizing lamp 33 is an ultraviolet sterilizing lamp for sterilizing and disinfecting the pure water in the pure water tank 31.

Specifically, the water inlet valve 32 comprises a first liquid level switch 321, the first liquid level switch 321 comprises a double-floating-ball liquid level switch, the double-floating-ball liquid level switch comprises an upper floating ball 3211 and a lower floating ball 3212,

when the liquid level in the pure water tank 31 is higher than the floating ball 3211, triggering the first liquid level switch 321 to close water inlet;

when the liquid level in the pure water tank 31 is lower than the lower floating ball 3212, triggering the first liquid level switch 321 to open water inlet; simple structure, convenient operation.

More specifically, the inlet valve 32 further includes a backup mechanical valve 322; the backup mechanical valve 322 is preferably a float valve, and when the first level switch 321 fails, the liquid level in the pure water tank 31 continuously rises, the backup mechanical valve 322 is triggered to close the water inlet into the pure water tank 31.

In addition, the heating module 4 includes a vacuum tank 41, a second liquid level switch 42 provided in the vacuum tank 41, a heat generating pipe 43, and a temperature sensor 44; the second liquid level switch 42 is used for controlling pure water in the pure water tank 31 to enter the vacuum tank 41; when the boiled water in the vacuum tank 41 is not used up, the heating tube 43 will have low power to keep the temperature of the pure water in the vacuum tank 41, so as to preheat the boiled water for the next heating.

The second liquid level switch 42 includes a float level switch, a float 421 is provided on the float level switch, a water drain valve 11 is provided on a connecting pipe between the water storage module 3 and the heating module 4, and when the liquid level in the vacuum tank 41 is lower than the float 421, the second liquid level switch 42 triggers the water drain valve 11 to open so that pure water in the water storage module 3 flows into the vacuum tank 41;

the utility model also discloses that the pure water tank 31 is positioned above the vacuum tank 41, when the water drain valve 11 opens a pipeline waterway between the pure water tank 31 and the vacuum tank 41, pure water in the pure water tank 31 flows into the vacuum tank 41 under the action of gravity;

the utility model also discloses a heating module 4 which further comprises a timing device, wherein the timing device is provided with preset time, and when the opening time of the water drain valve 11 reaches the preset time, the timing device triggers the water drain valve 11 to be closed;

during the preset time, the pure water in the pure water tank 31 will fill up the vacuum tank 41;

when the pure water tank 31 is filled with normal-temperature pure water in the pure water tank 31 into the vacuum tank 41, the water temperature in the vacuum tank 41 is lowered;

when the temperature sensor 44 detects that the water temperature in the vacuum tank 41 is reduced, the temperature sensor 44 triggers the heating tube 43 to heat until pure water in the vacuum tank 41 is boiled;

when the pure water in the vacuum tank 41 is boiled, the heating tube 43 continuously outputs low power to keep the pure water in the vacuum tank 41 warm until the pure water tank 31 is again filled with normal-temperature pure water into the vacuum tank 41, or the water temperature in the vacuum tank 41 is lower than the temperature of the heating tube 43 for keeping the pure water warm, the temperature sensor 44 triggers the heating tube 43 to heat the pure water in the vacuum tank 41.

Further, the cooling module 5 is a water cooling coil pipe, and the water cooling coil pipe is used for exchanging heat with pure water in the water storage module 3 so as to cool boiled water flowing out of the heating module 4; the water cooling coil is preferably in a spiral disc-shaped pipeline structure, the length of a waterway is prolonged, and the cooling efficiency of boiled water flowing out of the vacuum tank 41 is improved.

Further, an exhaust pipe 7 for exhausting the heating module 4 is arranged between the water storage module 3 and the heating module 4; the exhaust pipe 7 is used for communicating the vacuum tank 41 and the pure water tank 31 to exhaust water vapor boiling water in the vacuum tank 41.

Specifically, a filtering module 2 is further arranged between the water inlet 1 and the water storage module 3, a waste water outlet 8 is arranged on the filtering module 2, and a waste water electromagnetic valve 9 is arranged between the waste water outlet 8 and the filtering module 2; the filtering module 2 is used for filtering tap water into drinkable pure water and leading the pure water into the water storage module 3, and the waste water outlet 8 is used for leading out waste water generated by filtering tap water in the filtering module 2.

Specific embodiment II:

as shown in fig. 3, this embodiment is substantially the same as the first embodiment, and only the differences between the main structure and the first embodiment are described for the sake of simplicity, and the differences between the non-described portions of this embodiment and the first embodiment are: the cooling module 5 comprises a primary cooling device 51, a secondary cooling device 52 and a flow dividing device 53 arranged between the primary cooling device 51 and the secondary cooling device 52;

the heating module 4 is sequentially communicated with the primary cooling device 51, the diversion device 53 and the pure water outlet 6 to form a first cooling waterway;

the heating module 4 is sequentially communicated with the primary cooling device 51, the flow dividing device 53, the secondary cooling device 52 and the pure water outlet 6 to form a second cooling waterway; the diversion device 53 is preferably an electromagnetic valve, the temperature of the warm boiled water flowing out of the second cooling waterway is smaller than that of the warm boiled water flowing out of the first cooling waterway, the temperature of the warm boiled water flowing out of the second cooling waterway is preferably 45 ℃, and the temperature of the warm boiled water flowing out of the first cooling waterway is preferably 65 ℃.

The utility model also discloses a water suction pump 10 which is arranged between the pure water outlet 6 and the water storage module 3 and is used for sucking out normal-temperature pure water in the water storage module 3, and a heat-resistant water suction pump 12 which is arranged between the heating module 4 and the pure water outlet 6 and is used for sucking out boiled water in the heating module 4, wherein the heat-resistant water suction pump 12 is also communicated with the cooling module 5 and is used for guiding the boiled water in the heating module 4 into the cooling module 5 for cooling.

The working principle of this embodiment is as follows:

the utility model discloses a system capable of realizing warm boiled water, which comprises a water inlet 1, a water storage module 3, a heating module 4, a cooling module 5 and a pure water outlet 6 which are sequentially communicated through pipelines, wherein the pure water outlet 6 is respectively communicated with the water storage module 3, the heating module 4 and the cooling module 5 so that the pure water outlet 6 sequentially outputs warm water, hot water and warm boiled water, and the cooling module 5 is arranged in the water storage module 3 so as to cool the cooling module 5 through pure water in the water storage module 3; through pure water in the water storage module 3 and the boiled water in the cooling module 5 are subjected to heat exchange, so that the boiled water in the heating module 4 is cooled, thereby obtaining warm boiled water, no electric drive is needed, the structure is simple, the cooling energy consumption is reduced, the cooling effect is improved, and the energy waste is not easy to cause.

The above description of one embodiment provided in connection with the specific content does not set forth limitation to the specific implementation of the present utility model, and is not limited to the above designations but is not limited to english designations due to the different industry designations. The method, structure, etc. similar to or identical to those of the present utility model, or some technical deductions or substitutions are made on the premise of the inventive concept, should be regarded as the protection scope of the present utility model.

Claims (10)

1. A system for enabling warm water to be dispensed, comprising: including water inlet (1) through pipeline intercommunication in proper order, water storage module (3), heating module (4), cooling module (5) to and pure water delivery port (6), pure water delivery port (6) respectively with water storage module (3) heating module (4) cooling module (5) intercommunication is in order for pure water delivery port (6) export warm water, hot water and warm boiled water in proper order, cooling module (5) are located in water storage module (3) in order to pass through pure water in water storage module (3) is right cooling module (5) carries out the cooling down.

2. A system for enabling warm water according to claim 1, characterized in that said cooling module (5) comprises a primary cooling device (51), a secondary cooling device (52), and a shunt device (53) interposed between said primary cooling device (51) and said secondary cooling device (52);

the heating module (4) is sequentially communicated with the primary cooling device (51), the flow dividing device (53) and the pure water outlet (6) to form a first cooling waterway;

the heating module (4) is sequentially communicated with the primary cooling device (51), the flow dividing device (53), the secondary cooling device (52) and the pure water outlet (6) to form a second cooling waterway.

3. A system for enabling warm water according to claim 1, characterized in that said water storage module (3) comprises a pure water tank (31), a water inlet valve (32) provided on said pure water tank (31), and a UV disinfection lamp (33).

4. A system for enabling warm water according to claim 3, characterized in that said inlet valve (32) comprises a first level switch (321), said first level switch (321) comprising a double float level switch comprising an upper float (3211) and a lower float (3212),

when the liquid level in the pure water tank (31) is higher than the floating ball (3211), triggering the first liquid level switch (321) to close water inlet;

when the liquid level in the pure water tank (31) is lower than the lower floating ball (3212), the first liquid level switch (321) is triggered to open water inflow.

5. A system for enabling warm water according to claim 3, characterized in that said inlet valve (32) further comprises a back-up mechanical valve (322).

6. A system for enabling warm water according to claim 1, characterized in that said heating module (4) comprises a vacuum tank (41), a second level switch (42) provided inside said vacuum tank (41), a heating tube (43), and a temperature sensor (44).

7. The system for realizing warm boiled water according to claim 6, wherein the second liquid level switch (42) comprises a floating ball liquid level switch, a floating ball (421) is arranged on the floating ball liquid level switch, a water drain valve (11) is arranged on a connecting pipeline between the water storage module (3) and the heating module (4), and when the liquid level in the vacuum tank (41) is lower than the floating ball (421), the second liquid level switch (42) triggers the water drain valve (11) to open so that pure water in the water storage module (3) flows into the vacuum tank (41).

8. A system for enabling warm water according to claim 1, characterized in that said cooling module (5) is a water-cooled coil for heat exchange with the pure water in said water storage module (3) to cool down the water flowing from said heating module (4).

9. A system for enabling warm water according to claim 1, characterized in that between the water storage module (3) and the heating module (4) there is an exhaust pipe (7) for the exhaust of the heating module (4).

10. A system for realizing warm boiled water according to claim 1, characterized in that a filter module (2) is further arranged between the water inlet (1) and the water storage module (3), a waste water outlet (8) is arranged on the filter module (2), and a waste water electromagnetic valve (9) is arranged between the waste water outlet (8) and the filter module (2).