CN219289222U - Cooked water tea bar machine with quick heating and refrigerating module - Google Patents

Abstract

The utility model discloses a boiled water tea bar machine with a quick heating and refrigerating module, which comprises a water supply device, a water pump I, a water pump II, a water pump III, a three-way electromagnetic valve I, a three-way electromagnetic valve II, a cold heat exchanger, a heating module I, a water mixing valve II, a three-way piece, a cold tank and a water-vapor separation box, wherein the water supply device is connected with the water pump I; the cold-heat exchanger is connected with a second three-way electromagnetic valve, the second three-way electromagnetic valve is connected with a cold tank, the cold tank is connected with a third water pump, the third water pump is connected with a second water mixing valve, the second water mixing valve is connected with a first water mixing valve, the second three-way electromagnetic valve is connected with a second water mixing valve, and the first water mixing valve is connected with a water-steam separation box; the connection is waterway connection. The application can provide cooked water with various temperatures.

Description

Cooked water tea bar machine with quick heating and refrigerating module

Technical Field

The utility model relates to the technical field of tea bar machines, in particular to a boiled water tea bar machine with a quick heating and refrigerating module.

Background

The tea bar machine is novel drinking equipment, the problem that the traditional drinking machine needs to insert barreled water into the top end of the drinking machine in an inverted mode is avoided, and the drinking equipment is greatly convenient to use.

Most of the existing tea bar machines adopt couplers for heating, wait is needed when receiving hot water, and users cannot drink boiled water with the desired temperature immediately. In addition, bacteria can grow after the barreled water of the traditional tea bar machine is used for a period of time, the barreled water can be drunk after boiling, and if warm water is needed to be drunk, a long time is needed to wait, so that bad user experience is brought; in addition, the existing tea bar machine with the refrigerating function generally carries out direct refrigeration on normal-temperature water to obtain cold water, but the cold water is not boiled, and does not accord with sanitary habits.

In view of this, improvements to existing tea bar machines are needed.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a boiled water tea bar machine with a quick heating and refrigerating module, which can quickly provide boiled water with any temperature between cold water and boiled water in real time.

The utility model discloses a boiled water tea bar machine with a quick heating and refrigerating module, which comprises a water supply device, a water pump I, a water pump II, a water pump III, a three-way electromagnetic valve I, a three-way electromagnetic valve II, a cold heat exchanger, a heating module I, a water mixing valve II, a three-way piece, a cold tank and a water-vapor separation box, wherein the water supply device is connected with the water pump I, the water pump I is connected with the three-way electromagnetic valve I, the three-way electromagnetic valve I is connected with the cold heat exchanger, the cold heat exchanger is connected with the water pump II, the water pump II is connected with the heating module I, the heating module I is connected with the three-way piece, the three-way piece is connected with the cold heat exchanger, and the three-way piece is connected with the water mixing valve I; the cold-heat exchanger is connected with the two three-way electromagnetic valve, the two three-way electromagnetic valve is connected with the cold tank, the cold tank is connected with the three-phase water pump, the three-phase water pump is connected with the two water mixing valves, the two water mixing valves are connected with the first water mixing valve, the two three-way electromagnetic valve is connected with the two water mixing valves, and the first water mixing valve is connected with the water-steam separation box; the connection is waterway connection.

Preferably, a hot tank is installed between the cold-heat exchanger and the second water pump, the hot tank is connected with the cold-heat exchanger, and the hot tank is connected with the second water pump.

Preferably, a second heating module is installed on a waterway between the first water mixing valve and the water-vapor separation box, the second heating module is connected with the first water mixing valve, and the second heating module is connected with the water-vapor separation box.

Preferably, a second heating module is installed on a waterway between the first water mixing valve and the water-vapor separation box, the second heating module is connected with the first water mixing valve, and the second heating module is connected with the water-vapor separation box.

Preferably, a temperature sensor is installed on a waterway between the second water pump and the first heating module.

Preferably, a temperature sensor is installed on a waterway between the heating module I and the tee joint piece.

Preferably, a temperature sensor is arranged on a waterway between the first water mixing valve and the water-vapor separation box.

Preferably, two temperature sensors are installed on the waterway between the first water mixing valve and the water-vapor separation box, one temperature sensor is installed on the waterway between the second heating module and the first water mixing valve, and the other temperature sensor is installed on the waterway between the second heating module and the water-vapor separation box.

Preferably, a three-way electromagnetic valve III is arranged on a waterway between the cold-heat exchanger and the hot tank, the three-way electromagnetic valve III is connected with the cold-heat exchanger, and the three-way electromagnetic valve III is connected with the hot tank; a three-way electromagnetic valve IV is arranged on a waterway between the hot tank and the water pump II, the three-way electromagnetic valve IV is connected with the hot tank, and the three-way electromagnetic valve IV is connected with the water pump II; the three-way electromagnetic valve III is connected with the three-way electromagnetic valve IV.

Preferably, a refrigeration compressor is connected to the cold tank.

The beneficial effects of this application lie in:

the utility model can enable a user to drink water from cold water to boiled water and any temperature between the cold water and the boiled water, and the water at any temperature can be boiled water, thereby having the function of sterilization, having no need of waiting for real-time water outlet, greatly improving the use experience of the user and conforming to sanitary habits.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

fig. 1 is a schematic diagram of a connection structure of embodiment 1;

fig. 2 is a schematic diagram of the connection structure of embodiment 2;

FIG. 3 is a schematic diagram of the connection structure of embodiment 3;

fig. 4 is a schematic diagram of the connection structure of embodiment 4.

Reference numerals illustrate:

1. a water supply device; 21. a first water pump; 22. a second water pump; 23. a water pump III; 31. a three-way electromagnetic valve I; 32. a three-way electromagnetic valve II; 33. three-way electromagnetic valve III; 34. a three-way electromagnetic valve IV; 4. a cold-heat exchanger; 5. a hot pot; 61. a first heating module; 62. a heating module II; 71. a first water mixing valve; 72. a water mixing valve II; 8. a tee; 9. a cold tank; 91. a refrigeration compressor; 10. a water-vapor separation box; 11. a temperature sensor.

Detailed Description

Various embodiments of the utility model are disclosed in the following drawings, in which details of the practice are set forth in the following description for the purpose of clarity. However, it should be understood that these practical details are not to be taken as limiting the utility model. That is, in some embodiments of the utility model, these practical details are unnecessary. Moreover, for the sake of simplicity of the drawing, some well-known and conventional structures and elements are shown in the drawings in a simplified schematic manner.

It should be noted that all directional indications such as up, down, left, right, front, and rear … … in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture such as that shown in the drawings, and if the particular posture is changed, the directional indication is changed accordingly.

In addition, the descriptions of the "first", "second", etc. in this application are for descriptive purposes only and are not intended to specifically indicate a sequential or a cis-position, nor are they intended to limit the utility model, but are merely intended to distinguish between components or operations described in the same technical term, and are not to be construed as indicating or implying a relative importance or implying that the number of technical features indicated is not necessarily limited. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings in which:

example 1

Referring to fig. 1, a boiled water tea bar machine with a rapid heating and refrigerating module disclosed in this embodiment includes a water supply device 1, a first water pump 21, a second water pump 22, a third water pump 23, a first three-way electromagnetic valve 31, a second three-way electromagnetic valve 32, a cold heat exchanger 4, a hot tank 5, a first heating module 61, a first mixing valve 71, a second mixing valve 72, a three-way piece 8, a cold tank 9, a refrigerating compressor 91 and a water-vapor separation box 10, wherein the water supply device 1 is used for storing and providing a filtered water source, the water supply device 1 has a water outlet, the first water pump 21, the second water pump 22 and the third water pump 23 are used for pumping water, the first water pump 21, the second water pump 22 and the third water pump 23 are all provided with a water inlet and a water outlet, the first three-way electromagnetic valve 31 and the second three-way electromagnetic valve 32 are all provided with three interfaces a, b and c, and the water outlet of the water supply device 1 is connected with the water inlet of the first water pump 21 through a waterway pipeline and the water outlet of the first water pump 21 is connected with the interface of the third electromagnetic valve 31 through a waterway pipeline.

Referring to fig. 1, the cold-heat exchanger 4 adopts a plate heat exchanger, the cold-heat exchanger 4 has a, b, c, d interfaces, wherein the interface a is an inlet of a cold water channel of the cold-heat exchanger 4, the interface b is an outlet of a cold water channel of the cold-heat exchanger 4, the interface c is an inlet of a hot water channel of the cold-heat exchanger 4, the interface d is an outlet of a hot water channel of the cold-heat exchanger 4, and the interface b of the three-way electromagnetic valve 31 is connected with the interface a of the cold-heat exchanger 4 through a waterway pipeline.

Referring to fig. 1, a hot tank 5 is used for temporarily storing a part of drinking water flowing out of a cold-heat exchanger 4, and preheating the water, so that the water is firstly burned to a certain temperature when in use, and the flow of the water is ensured to be larger when the water is required to be discharged by a user; the hot tank 5 is provided with a water inlet and a water outlet, the port b of the cold-heat exchanger 4 is connected with the water inlet of the hot tank 5 through a waterway pipeline, and the water outlet of the hot tank 5 is connected with the water inlet of the second water pump 22 through a waterway pipeline; the first heating module 61 is used for heating water flowing through the first heating module 61, the first heating module 61 is provided with a water inlet and a water outlet, and the water outlet of the second water pump 22 is connected with the water inlet of the first heating module 61 through a waterway pipeline.

Referring to fig. 1, the three-way piece 8 is a three-way pipe, the three-way piece 8 is provided with three interfaces a, b and c, the water outlet of the first heating module 61 is communicated with the interface b of the three-way piece 8 through a waterway pipeline, and the interface a of the three-way piece 8 is communicated with the interface c of the cold-heat exchanger 4 through a waterway pipeline; in addition, the first water mixing valve 71 and the second water mixing valve 72 are respectively provided with three interfaces a, b and c, wherein the interfaces a and b are water inlets, the interface c is a water outlet, the proportion between the two water inlets a and b can be adjusted between 0 and 1, the interface c of the three-way piece 8 is communicated with the interface b of the first water mixing valve 71 through a waterway pipeline, and the interface a of the first water mixing valve 71 is communicated with the interface c of the second water mixing valve 72 through the waterway pipeline.

Referring to fig. 1, the d interface of the cold-heat exchanger 4 is connected with the a interface of the three-way electromagnetic valve two 32 through a waterway pipeline, and the c interface of the three-way electromagnetic valve two 32 is communicated with the a interface of the water mixing valve two 72 through a waterway pipeline; the cold tank 9 is used for refrigerating water and temporarily storing low-temperature water, so that the water can be cooled below room temperature for use, and the cold tank 9 is connected with the refrigeration compressor 91, so that the refrigeration compressor 91 can provide a refrigeration source for the cold tank 9; the cold tank 9 is provided with a water inlet and a water outlet, the water inlet of the cold tank 9 is communicated with the b interface of the three-way electromagnetic valve II 32 through a waterway pipeline, the water outlet of the cold tank 9 is communicated with the water inlet of the water pump III 23 through a waterway pipeline, and the water outlet of the water pump III 23 is communicated with the b interface of the water mixing valve II 72 through a waterway pipeline; the c interface of the first water mixing valve 71 is connected with the water-steam separation box 10 through a waterway pipeline.

Referring to fig. 1, a water-vapor separation box 10 is used for separating hot vapor from drinking water, the water-vapor separation box 10 has two inlets a and b and an outlet c, the c interface of a water mixing valve 71 is connected with the a inlet of the water-vapor separation box 10 through a waterway pipeline, the b inlet of the water-vapor separation box 10 is communicated with the c interface of a three-way electromagnetic valve 31 through a waterway pipeline, and the c outlet of the water-vapor separation box 10 is the end point of the waterway for a user to take water.

Referring to fig. 1, a temperature sensor 11 is installed on the waterway between the second water pump 22 and the first heating module 61, a temperature sensor 11 is also installed on the waterway between the first heating module 61 and the b-port of the three-way member 8, a temperature sensor 11 is also installed on the waterway between the c-port of the first mixing valve 71 and the a-port of the water-vapor separation cartridge 10, and the temperature sensor 11 is used for detecting the water temperature in the waterway so as to accurately obtain the water temperature in the waterway.

When a user takes water, the following three conditions exist:

in the first case, when the interface a and the interface c of the three-way electromagnetic valve 31 are opened and the interface b is closed, the water pump 21 directly sends the normal-temperature water in the water supply device 1 into the interface b of the water-vapor separation box 10 through the interface a and the interface c of the three-way electromagnetic valve 31, and the normal-temperature water directly flows out through the interface c of the water-vapor separation box 10 for use.

When the interface a and the interface b of the three-way electromagnetic valve I31 are opened and the interface c is closed, and the interface a and the interface c of the three-way electromagnetic valve II 32 are opened and the interface b is closed, under the action of a water pump, water in the water supply device 1 enters the hot tank 5 through the interface a and the interface b of the three-way electromagnetic valve I31 and the interface a and the interface b of the cold heat exchanger 4 for temporary storage or preheating, the water in the hot tank 5 is pumped into the heating module I61 by the water pump II 22 to be boiled, the boiled water enters the interface b of the three-way element 8 through the heating module I61 and then enters two branches, wherein the boiled water flowing out from the interface a of the three-way element 8 enters the interface c of the cold heat exchanger 4 and flows out from the interface d of the cold heat exchanger 4, exchanges heat with the water flowing through the interfaces a and b of the cold heat exchanger 4, cools down, then flows through the interface a and the interface c of the three-way electromagnetic valve II 32, passes through the interface a and the interface c of the mixing valve II 72 and finally enters the inlet a of the mixing valve I71; the cooked water flowing out of the interface c of the three-way piece 8 directly enters the interface b of the first water mixing valve 71, is mixed with the relatively low temperature water entering the interface a of the first water mixing valve 71, and flows out of the interface c of the first water mixing valve 71; by changing the mixing proportion of the a and b interfaces of the first water mixing valve 71, cooked water in a higher temperature range can be obtained; the whole water outlet process ensures that the hot tank 5 is also supplemented with water at the same time, and the balance of the water supplementing and water outlet flows of the hot tank 5 is ensured.

In the third case, when the interfaces a and b of the first three-way electromagnetic valve 31 are opened and the interface c is closed and all the interfaces of the second three-way electromagnetic valve 32 are opened, the water entering the interface of the first water mixing valve 71a needs to be mixed with the boiled water temporarily stored in the cold tank 9 at first, at the second water mixing valve 72, and then enters the first water mixing valve 71 to be mixed with the boiled water which is not cooled; by changing the mixing ratio of the first and second ports 71a and 72 b and the mixing ratio of the second and third ports, boiled water in a wider temperature range can be obtained; the whole water outlet process ensures that the hot tank 5 is also filled with water at the same time, so that the water filling of the hot tank 5 and the flow balance of the water outlet are ensured, the water in the cold tank 9 is used first and then is filled, the water outlet of the cold tank 9 and the water filling of the cold tank 9 are two mutually independent processes, and the proper water temperature in the cold tank 9 is ensured when the water in the cold tank 9 needs to be taken.

Example 2

The difference between this embodiment and embodiment 1 is that a second heating module 62 is added, the second heating module 62 is installed on the waterway between the c interface of the first water mixing valve 71 and the a interface of the water-vapor separation box 10, the second heating module 62 has a water inlet and a water outlet, the water inlet of the second heating module 62 is communicated with the c interface of the first water mixing valve 71 through a waterway pipeline, the water outlet of the second heating module 62 is communicated with the a interface of the water-vapor separation box 10 through a waterway pipeline, and the second heating module 62 is used for secondary heating, so as to ensure that the water taken by the user can reach the set temperature.

In addition, two temperature sensors 11 are arranged on the waterway between the c interface of the first water mixing valve 71 and the a interface of the water-vapor separation box 10, one temperature sensor 11 is arranged on the waterway between the c interface of the first water mixing valve 71 and the water inlet of the second heating module 62, and the other temperature sensor 11 is arranged on the waterway between the water outlet of the second heating module 62 and the a interface of the water-vapor separation box 10.

Example 3

The difference between this embodiment and embodiment 1 is that three-way solenoid valve three 33 and three-way solenoid valve four 34 are added, three-way solenoid valve three 33 and three-way solenoid valve four 34 each have three interfaces a, b, c, wherein three-way solenoid valve three 33 is installed on the waterway between the b interface of cold heat exchanger 4 and the water inlet of hot tank 5, three-way solenoid valve four 34 is installed on the waterway between the water outlet of hot tank 5 and the water inlet of water pump two 22; the interface a of the three-way electromagnetic valve III 33 is communicated with the interface b of the cold and heat exchanger 4 through a waterway pipeline, the interface b of the three-way electromagnetic valve III 33 is communicated with the water inlet of the hot tank 5 through a waterway pipeline, the interface a of the three-way electromagnetic valve IV 34 is communicated with the water inlet of the water pump II 22 through a waterway pipeline, the interface b of the three-way electromagnetic valve IV 34 is communicated with the water outlet of the hot tank 5 through a waterway pipeline, and the interface c of the three-way electromagnetic valve III 33 is communicated with the interface c of the three-way electromagnetic valve IV 34 through a waterway pipeline.

This embodiment is the same as embodiment 1 when the a, b interfaces of the three-way solenoid valve three 33 and the three-way solenoid valve four 34 are opened, but the c interface of the three-way solenoid valve three 33 and the three-way solenoid valve four 34 is closed; when the interfaces a and c of the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 are opened, but the interface b of the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 is closed, water flow bypasses the hot tank 5 under the action of the water pump, and when the water in the hot tank 5 is used up, the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 short-circuit the hot tank 5, namely, the water flow directly flows into the three-way electromagnetic valve IV 34 from the three-way electromagnetic valve III 33 and then flows to the water pump II 22, so that the smoothness of a waterway is ensured.

Example 4

The difference between this embodiment and embodiment 2 is that three-way solenoid valve three 33 and three-way solenoid valve four 34 are added, three-way solenoid valve three 33 and three-way solenoid valve four 34 each have three interfaces a, b and c, wherein three-way solenoid valve three 33 is installed on the waterway between the interface b of cold heat exchanger 4 and the water inlet of hot tank 5, three-way solenoid valve four 34 is installed on the waterway between the water outlet of hot tank 5 and the water inlet of water pump two 22; the interface a of the three-way electromagnetic valve III 33 is communicated with the interface b of the cold and heat exchanger 4 through a waterway pipeline, the interface b of the three-way electromagnetic valve III 33 is communicated with the water inlet of the hot tank 5 through a waterway pipeline, the interface a of the three-way electromagnetic valve IV 34 is communicated with the water inlet of the water pump II 22 through a waterway pipeline, the interface b of the three-way electromagnetic valve IV 34 is communicated with the water outlet of the hot tank 5 through a waterway pipeline, and the interface c of the three-way electromagnetic valve III 33 is communicated with the interface c of the three-way electromagnetic valve IV 34 through a waterway pipeline.

This embodiment is the same as embodiment 2 when the a, b interfaces of the three-way solenoid valve three 33 and the three-way solenoid valve four 34 are opened, but the c interface of the three-way solenoid valve three 33 and the three-way solenoid valve four 34 is closed; when the interfaces a and c of the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 are opened, but the interface b of the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 is closed, water flow bypasses the hot tank 5 under the action of the water pump, and when the water in the hot tank 5 is used up, the three-way electromagnetic valve III 33 and the three-way electromagnetic valve IV 34 short-circuit the hot tank 5, namely, the water flow directly flows into the three-way electromagnetic valve IV 34 from the three-way electromagnetic valve III 33 and then flows to the water pump II 22, so that the smoothness of a waterway is ensured.

In summary, the utility model can enable users to drink water from cold water to boiled water and any temperature between the cold water and the boiled water, and the water at any temperature can be boiled water, thereby having the function of sterilization, having no need of waiting for real-time water outlet, greatly improving the use experience of users and conforming to sanitary habits.

The above are merely embodiments of the present utility model, and are not intended to limit the present utility model. Various modifications and variations of the present utility model will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, or the like, which is within the spirit and principles of the present utility model, should be included in the scope of the claims of the present utility model.

Claims (10)

1. The boiled water tea bar machine with the quick heating and refrigerating module is characterized by comprising a water supply device (1), a first water pump (21), a second water pump (22), a third water pump (23), a first three-way electromagnetic valve (31), a second three-way electromagnetic valve (32), a cold heat exchanger (4), a first heating module (61), a first water mixing valve (71), a second water mixing valve (72), a three-way piece (8), a cold tank (9) and a water vapor separation box (10), wherein the water supply device (1) is connected with the first water pump (21), the first water pump (21) is connected with the first three-way electromagnetic valve (31), the first three-way electromagnetic valve (31) is connected with the cold heat exchanger (4), the second water pump (22) is connected with the first heating module (61), the first heating module (61) is connected with the three-way piece (8), the three-way piece (8) is connected with the cold heat exchanger (4), and the first three-way piece (8) is connected with the water mixing valve (71).

The cold-heat exchanger (4) is connected with the three-way electromagnetic valve II (32), the three-way electromagnetic valve II (32) is connected with the cold tank (9), the cold tank (9) is connected with the water pump III (23), the water pump III (23) is connected with the water mixing valve II (72), the water mixing valve II (72) is connected with the water mixing valve I (71), the three-way electromagnetic valve II (32) is connected with the water mixing valve II (72), and the water mixing valve I (71) is connected with the water-vapor separation box (10); the connection is waterway connection.

2. The boiled water tea bar machine with rapid heating and refrigerating module according to claim 1, wherein a hot tank (5) is installed between the cold heat exchanger (4) and the water pump two (22), the hot tank (5) is connected with the cold heat exchanger (4), and the hot tank (5) is connected with the water pump two (22).

3. The boiled water tea bar machine with rapid heating and refrigerating module according to claim 1, wherein a heating module II (62) is installed on a waterway between the water mixing valve I (71) and the water-vapor separation box (10), the heating module II (62) is connected with the water mixing valve I (71), and the heating module II (62) is connected with the water-vapor separation box (10).

4. The boiled water tea bar machine with rapid heating and refrigerating module according to claim 2, wherein a heating module II (62) is installed on a waterway between the water mixing valve I (71) and the water-vapor separation box (10), the heating module II (62) is connected with the water mixing valve I (71), and the heating module II (62) is connected with the water-vapor separation box (10).

5. The boiled water tea bar machine with rapid heating and cooling module according to any one of claims 1 to 4, wherein a temperature sensor (11) is installed on a waterway between the second water pump (22) and the first heating module (61).

6. The boiled water tea bar machine with rapid heating and refrigerating module according to claim 5, wherein a temperature sensor (11) is installed on a waterway between the heating module one (61) and the tee (8).

7. The boiled water tea bar machine with rapid heating and refrigerating module according to any one of claims 1 to 4, wherein a temperature sensor (11) is installed on a waterway between the first water mixing valve (71) and the water-vapor separation cartridge (10).

8. The boiled water tea bar machine with rapid heating and cooling module according to claim 3 or 4, wherein two temperature sensors (11) are installed on a waterway between the first water mixing valve (71) and the water-vapor separation cartridge (10), one temperature sensor (11) is installed on a waterway between the second heating module (62) and the first water mixing valve (71), and the other temperature sensor (11) is installed on a waterway between the second heating module (62) and the water-vapor separation cartridge (10).

9. The boiled water tea bar machine with the rapid heating and refrigerating module according to claim 2, wherein a three-way electromagnetic valve III (33) is installed on a waterway between the cold heat exchanger (4) and the hot tank (5), the three-way electromagnetic valve III (33) is connected with the cold heat exchanger (4), and the three-way electromagnetic valve III (33) is connected with the hot tank (5);

a three-way electromagnetic valve IV (34) is arranged on a waterway between the hot tank (5) and the water pump II (22), the three-way electromagnetic valve IV (34) is connected with the hot tank (5), and the three-way electromagnetic valve IV (34) is connected with the water pump II (22);

the three-way electromagnetic valve III (33) is connected with the three-way electromagnetic valve IV (34).

10. The boiled water tea bar machine with rapid heating and refrigerating module according to any one of claims 1 to 4, characterized in that the cold tank (9) is connected with a refrigerating compressor (91).

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