CN209922970U - Long-acting rapid electronic refrigeration system for water purification and drinking all-in-one machine - Google Patents

Abstract

The utility model relates to a water purifier design technical field discloses a long-term quick electronic refrigeration system for water purification and drinking all-in-one, including former water tank, composite filter core, booster pump, filtration filter core, pure water case, cold water storage cistern, first TEC semiconductor cooler, still including inside injection have the circulating water and supply the condenser tube of the end embedding of giving out heat of first TEC semiconductor cooler, be used for carrying out radiating heat abstractor to the circulating water in the condenser tube. The heat release end of the first TEC semiconductor cooler is embedded into the cooling water pipe, so that heat of the heat release end of the first TEC semiconductor cooler enters the circulating water, the heat dissipation device is used for dissipating heat of the circulating water, the temperature of the circulating water is reduced through the heat dissipation device, the cooled circulating water can continue to dissipate heat of the heat release end of the first TEC semiconductor cooler, and finally heat dissipation of the heat release end of the first TEC semiconductor cooler can be achieved conveniently.

Description

Long-acting rapid electronic refrigeration system for water purification and drinking all-in-one machine

Technical Field

The utility model relates to a water purification and drinking all-in-one machine designs technical field, in particular to water purification and drinking all-in-one is with long-term quick electronic refrigeration system.

Background

The water purification and drinking integrated machine integrates water purification and drinking functions, meets multiple requirements of household drinking water, and is a great change of household drinking water modes.

At present, Chinese patent with publication number CN204569634U and publication date 2015, 8 and 19 discloses an installation-free portable instant heating water purifier with a cleanable filter element, which comprises a shell, wherein the shell is sequentially provided with a raw water tank, a self-absorption booster pump, a composite filter element, an RO reverse osmosis membrane, a sterilization device, a water purification tank, a water suction pump, a heating device and a water-vapor separation box which are connected through pipelines; a flushing valve is also arranged between the raw water tank and the RO reverse osmosis membrane through a pipeline; the shell is also provided with a rotary integrated key, and the rotary integrated key is connected with the water pump and the heating device through lines; a filtering cloth bag is arranged in a tank body of the raw water tank, the filtering cloth bag is connected with a self-absorption booster pump through a pipeline, and a TDS probe is further arranged between the filtering cloth bag and the self-absorption booster pump through a pipeline.

The installation-free portable instant heating water purifier with the cleanable filter element obtains cleaner pure water in the water purification box through the composite filter element, the RO reverse osmosis membrane and the sterilization device; wherein when being in summer and people need drink comparatively icy water, this take portable instantaneous water purification machine of exempting from to install of washable filter core often still can set up a cold water tank of connecting the pure water case, and is provided with the TEC semiconductor refrigerator that is used for the refrigeration of heat absorption on the cold water tank to the realization is cooled off the water that the pure water case entered into in the cold water tank.

Wherein the TEC semiconductor refrigerator is made by using Peltier effect of semiconductor material; the peltier effect is a phenomenon in which when a direct current passes through a couple composed of two semiconductor materials, one end absorbs heat and the other end releases heat; the fan is usually additionally arranged at the heat release end of the TEC semiconductor refrigerator through a bolt in order to accelerate the heat release of the heat release end of the TEC semiconductor refrigerator, at the moment, the heat release end of the TEC semiconductor refrigerator mainly depends on the fan for heat release during working, so the using time of the fan is often longer, the required rotating speed is higher, the noise emitted by the fan is higher, meanwhile, the refrigerating efficiency of the fan for refrigerating the heat release end of the TEC semiconductor refrigerator is also lower, and finally great trouble is brought to the heat release of the heat release end of the TEC semiconductor refrigerator.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a long-term quick electronic refrigeration system for water purification and drinking all-in-one machine can dispel the heat to the end heat of releasing heat of first TEC semiconductor cooler with higher speed.

The above technical purpose of the present invention can be achieved by the following technical solutions: the utility model provides a clean drinking water is long-term quick electron refrigerating system for all-in-one, includes former water tank, the composite filter element who is connected with former water tank, be located the booster pump between former water tank and the composite filter element, the filtration filter core of being connected with composite filter element, the pure water case of being connected with filtration filter core, the cold water tank of being connected with the pure water case, set up the first TEC semiconductor cooler on the cold water tank, be provided with the inlet tube of being connected with the pure water case on the cold water tank, supply the outlet pipe that the water after the cooling was discharged, filter the filter core for RO filter core or receive the filter core of straining, still include inside pour into have the circulating water and supply the condenser tube of the heat release end embedding of first TEC semiconductor cooler, be used for carrying.

The utility model discloses a further set up to: one end of the cooling water pipe is connected with the waste water outlet end of the filtering filter element, and the other end of the cooling water pipe is connected with the original water tank.

The utility model discloses a further set up to: the heat dissipation device comprises a heat dissipation pipe and an air cooling radiator, wherein the heat dissipation pipe is integrally arranged on the cooling water pipe and extends in an S shape, and the air cooling radiator is arranged on the heat dissipation pipe.

The utility model discloses a further set up to: the heat dissipation device comprises a first circulating water pump, a circulating water pipe, a second circulating water pump and a heat exchange assembly, wherein the first circulating water pump is connected with two ends of the cooling water pipe at the water inlet end and the water outlet end respectively, the two ends of the first circulating water pump are communicated with the original water tank, the second circulating water pump is arranged on the circulating water pipe, and the heat exchange assembly is arranged between the circulating water pipe and the cooling water pipe.

The utility model discloses a further set up to: the heat exchange assembly comprises a spiral first coil pipe arranged on the cooling water pipe, a second coil pipe arranged on the circulating water pipe and distributed with the first coil pipe in a staggered mode, and the first coil pipe and the second coil pipe are mutually abutted.

The utility model discloses a further set up to: and the cooling water pipe is also provided with a plurality of second TEC semiconductor refrigerators with heat absorption ends embedded in the cooling water pipe.

The utility model discloses a further set up to: and a low-speed cooling fan is arranged on the heat release end of the second TEC semiconductor cooler.

The utility model discloses a further set up to: and the circulating water in the cooling water pipe is pure water in the pure water tank.

The utility model discloses a further set up to: and one end of the water outlet pipe, which is positioned in the cold water tank, is positioned at the lower end of the cold water tank.

To sum up, the utility model discloses following beneficial effect has:

1. when heat of the heat release end of the first TEC semiconductor refrigerator needs to be dissipated, the heat release end of the first TEC semiconductor refrigerator is embedded into the cooling water pipe, so that the heat of the heat release end of the first TEC semiconductor refrigerator enters the circulating water, and the temperature of the circulating water can rise due to the fact that the circulating water obtains the heat of the heat release end of the first TEC semiconductor refrigerator; meanwhile, the heat dissipation device is used for dissipating heat of the circulating water, so that the temperature of the circulating water is reduced through the heat dissipation device, the cooled circulating water can continue to dissipate heat of the heat release end of the first TEC semiconductor refrigerator, and finally, heat dissipation of the heat release end of the first TEC semiconductor refrigerator can be conveniently achieved;

2. one end of a cooling water pipe is connected with a wastewater outlet end of a filtering filter element, the other end of the cooling water pipe is connected with a raw water tank, wastewater discharged from the wastewater outlet end of the filtering filter element can enter the cooling water pipe under the action of a booster pump, the wastewater can enter the raw water tank after passing through a heat release end of a first TEC semiconductor refrigerator, and meanwhile, water in the raw water tank can be injected into the filtering filter element again for filtering, so that continuous flowing of circulating water in the cooling water pipe is realized, at the moment, the circulating water can have a lower temperature, and heat dissipation of the heat release end of the first TEC semiconductor refrigerator is facilitated through the circulating water;

3. the cooling pipe arranged on the cooling water pipe is utilized, the cooling pipe extends in an S shape, the length of the cooling pipe can be longer, when circulating water flows in the cooling pipe, a longer path can be needed, the circulating water can be conveniently and constantly exchanged with the outside temperature through the pipe wall of the cooling water pipe, the temperature of the circulating water can be reduced, and finally the heat release end of the first TEC semiconductor refrigerator can be favorably cooled through the circulating water;

meanwhile, the air-cooled radiator is used for radiating heat of the radiating pipe, so that the temperature of circulating water flowing in the radiating pipe is further reduced, and finally the heat radiating end of the first TEC semiconductor refrigerator can be radiated by the circulating water;

4. the circulating water is pushed to circulate in the cooling water pipe through the first circulating water pump, and along with the circulation of the circulating water, the circulating water can continuously exchange the temperature with the outside through the pipe wall of the cooling water pipe, and at the moment, the temperature of the circulating water can be reduced; by utilizing the circulating water pipe connected with the original water tank, wherein the heat exchange assembly arranged between the circulating water pipe and the cooling water pipe is utilized, the heat exchange assembly can transfer the heat of the circulating water to the water in the circulating water pipe, so that the temperature of the circulating water is further reduced; when the temperature of the circulating water is reduced, the circulating water can dissipate heat of the heat release end of the first TEC semiconductor refrigerator conveniently in a long-acting manner;

5. by utilizing the first coil and the second coil in the heat exchange assembly, wherein the first coil is communicated with the cooling water pipe, the second coil is communicated with the circulating water pipe, and the first coil and the second coil are distributed in a staggered manner and mutually abutted, when water in the first coil and the second coil flows, heat in high-temperature water can be transferred to heat in low-temperature water, so that the heat transfer effect is realized; the circulating water in the cooling water pipe obtains the heat of the heat release end of the first TEC semiconductor refrigerator, so that the temperature of the water in the cooling water pipe is high, the water in the second coil pipe can obtain the heat of the water in the cooling water pipe, and the temperature of the circulating water can be reduced finally, so that the heat of the heat release end of the first TEC semiconductor refrigerator can be conveniently dissipated; meanwhile, the first coil and the second coil are both spiral, so that the lengths of the first coil and the second coil are both long, and when the first coil and the second coil are abutted together, the water in the first coil and the water in the second coil can be subjected to sufficient heat exchange, and finally, the temperature of circulating water can be reduced rapidly, so that the heat of a heat release end of the first TEC semiconductor refrigerator can be further conveniently dissipated;

6. the plurality of second TEC semiconductor refrigerators are further arranged on the cooling water pipe, wherein the heat absorption ends of the second TEC semiconductor refrigerators are embedded in the cooling water pipe, and the plurality of second TEC semiconductor refrigerators can further cool the circulating water in the cooling water pipe, so that the temperature of the circulating water can be rapidly reduced, and the heat of the heat release end of the first TEC semiconductor refrigerator can be further conveniently dissipated;

7. the heat dissipation of the heat release end of the second TEC semiconductor cooler can be accelerated by utilizing the low-speed heat dissipation fan arranged on the heat release end of the second TEC semiconductor cooler, so that the rapid refrigeration of the second TEC semiconductor cooler is facilitated; meanwhile, as the cooling of the circulating water is not completely dependent on the second TEC semiconductor cooler, the requirements on the service time and the rotating speed of the low-speed cooling fan are not high, so that the service life of the low-speed cooling fan can be prolonged, and the frequency of replacing the low-speed cooling fan is reduced;

8. the circulating water in the cold water pipe is used as the pure water in the pure water tank, and impurities in the pure water are removed through the purification of the purification component, so that scale is not easily generated when the pure water circulates in the cooling water pipe, the rapid circulation of the circulating water in the cooling water pipe is facilitated, and the possibility of blockage of the cooling water pipe can be reduced;

9. because cold water and hot water are the state that cold water is hot water under when together, so utilize the one end that the inlet tube is located the cold water tank to be located the upper end of cold water tank, the one end that the outlet pipe is located the cold water tank simultaneously is located the lower extreme of cold water tank, can discharge through the outlet pipe fast after the cold water in the cold water tank forms, be favorable to people to obtain cold water fast.

Drawings

Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention;

fig. 2 is a schematic structural view of the heat dissipating device in embodiment 1;

fig. 3 is a schematic structural diagram of embodiment 2 of the present invention.

Reference numerals: 1. a raw water tank; 2. a composite filter element; 3. a booster pump; 4. a filter element; 5. a pure water tank; 6. a cold water tank; 61. a water inlet pipe; 62. a water outlet pipe; 7. a first TEC semiconductor refrigerator; 8. a cooling water pipe; 81. a second TEC semiconductor refrigerator; 811. a low-speed heat-dissipating fan; 9. a heat sink; 901. a radiating pipe; 902. an air-cooled radiator; 91. a first circulating water pump; 92. a circulating water pipe; 93. a second circulating water pump; 94. a heat exchange assembly; 941. a first coil pipe; 942. a second coil.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example 1: a long-acting rapid electronic refrigeration system for a water purification and drinking all-in-one machine is disclosed, referring to fig. 1, and comprises a raw water tank 1, a composite filter element 2, a booster pump 3, a filter element 4, a pure water tank 5, a cold water tank 6 and a first TEC semiconductor refrigerator 7; wherein, the raw water tank 1 is connected with the composite filter element 2 through a water pipe, the booster pump 3 is arranged on the water pipe between the raw water tank 1 and the composite filter element 2, and the water in the raw water tank 1 is pressed into the composite filter element 2 through the booster pump 3.

Referring to fig. 1, the filtering core is an RO filter core or a nanofiltration core, and both the RO filter core and the nanofiltration core are a prior art and are not described herein again; wherein the filtering core 4 is also connected with the composite filtering core 2 through a water pipe, and the pure water outlet end of the filtering core 4 is connected with the pure water tank 5 through a water pipe, wherein the water pipe between the pure water tank 5 and the filtering core 4 is connected with a one-way valve; meanwhile, the water outlet of the pure water tank 5 is also connected with a water pipe, a water outlet pump and an electric heating module are installed on the water pipe, and the pure water is heated through the electric heating module, so that people can drink hot water.

Referring to fig. 1, a water inlet pipe 61 is provided on the cold water tank 6, and one end of the water inlet pipe 61 is communicated with the cold water tank 6 and the other end is communicated with the pure water tank 5; meanwhile, the cold water tank 6 is also connected with a water outlet pipe 62, and the water outlet pipe 62 is used for discharging cooled water; wherein, the end of the inlet pipe 61 in the cold water tank 6 is positioned at the upper end of the cold water tank 6, the end of the outlet pipe 62 in the cold water tank 6 is positioned at the lower end of the cold water tank 6, and the outlet pipe 62 is also connected with an outlet valve.

Referring to fig. 1, a first TEC semiconductor cooler 7, which is made using the peltier effect of a semiconductor material, is fixed to a side wall of a cold water tank 6 by bolts; the peltier effect is a phenomenon in which when a direct current passes through a couple composed of two semiconductor materials, one end absorbs heat and the other end releases heat; meanwhile, the heat absorption end of the first TEC semiconductor cooler 7 is located inside the cold water tank 6 and the heat emission end is located outside the cold water tank 6.

Referring to fig. 1, a cooling water pipe 8 and a heat sink 9 are further disposed in the long-acting rapid electronic refrigeration system for water purifier, wherein circulating water is injected into the cooling water pipe 8, and a heat release end of the first TEC semiconductor refrigerator 7 is embedded in the cooling water pipe, so that the heat release end of the first TEC semiconductor refrigerator 7 contacts with the circulating water; and the heat dissipation device 9 is used for cooling and dissipating heat of the circulating water in the cooling water pipe 8.

Referring to fig. 1 and 2, one end of a cooling water pipe 8 is connected with a wastewater outlet end of a filter element 4, and the other end is connected with a raw water tank 1; meanwhile, the heat dissipation device 9 includes a heat dissipation pipe 901 and an air-cooled heat sink 902, wherein the heat dissipation pipe 901 is integrally arranged on the cooling water pipe 8, the heat dissipation pipe 901 extends in an S-shape, and the air-cooled heat sink 902 is arranged on the heat dissipation pipe 901, so that the heat dissipation pipe 901 is dissipated through the air-cooled heat sink 902; the air-cooled heat sink 902 is a prior art, and is not described herein.

The principle is as follows: utilize condenser tube 8's one end and the waste water outlet end of filtering filter core 4 to be connected and the other end is connected with former water tank 1, waste water from filtering filter core 4's waste water outlet end exhaust can enter into condenser tube 8 under booster pump 3's effect, and these waste water can enter into former water tank 1 behind the end of giving out heat through first TEC semiconductor cooler 7 in, simultaneously water in the former water tank 1 can pour into again and filter in filtering filter core 4, thereby realize the continuous flow of 8 internal recycle waters of condenser tube, can be favorable to the circulating water to have a lower temperature this moment, thereby be favorable to dispelling the heat through the end of giving out heat of circulating water to first TEC semiconductor cooler 7.

Utilize the cooling tube 901 that sets up on condenser tube 8 simultaneously, and cooling tube 901 is the extension of S-shaped, the length of cooling tube 901 can be than longer this moment, can need pass through longer distance when the circulating water flows in cooling tube 901, can make things convenient for the circulating water to ceaselessly carry out the temperature exchange through 8 pipe walls of condenser tube and the external world this moment, thereby be favorable to reducing the temperature of circulating water, finally can be favorable to dispelling the heat through the heat release end of circulating water to first TEC semiconductor cooler 7.

Example 2: the utility model provides a long-term quick electronic refrigeration system for water purification and drinking all-in-one, refer to fig. 3, with embodiment 1's difference lie in condenser tube 8's connection and heat abstractor 9, this kind of heat abstractor 9 includes first circulating water pump 91, condenser tube 92, second circulating water pump 93 and heat exchange assembly 94, wherein the end of intaking and play water end of first circulating water pump 91 are connected with the both ends of condenser tube 8 respectively, can satisfy the needs of the interior circulating water self-loopa of condenser tube 8 through first circulating water pump 91 provides power this moment, wherein the circulating water in condenser tube 8 is the pure water in pure water case 5.

Referring to fig. 3, the heat release end of the first TEC semiconductor cooler 7 is embedded in the chilled water pipe so that the heat release end of the first TEC semiconductor cooler 7 is in contact with the circulating water; when the first circulating water pump 91 drives the circulating water to circularly flow in the cooling water pipe 8, the heat of the heat release end of the first TEC semiconductor cooler 7 can be dissipated by the circulating water.

Referring to fig. 3, the cooling water pipe 8 is further provided with a plurality of second TEC semiconductor refrigerators 81 having heat absorbing ends embedded in the cooling water pipe 8, wherein a low-speed heat dissipating fan 811 is fixed to a heat releasing end of the second TEC semiconductor refrigerator 81 by a bolt; at this time, the second TEC semiconductor cooler 81 can further cool the circulating water in the cooling water pipe 8, thereby facilitating to rapidly reduce the temperature of the circulating water.

Referring to fig. 3, both ends of the water circulation pipe 92 are connected to the raw water tank 1, and the second water circulation pump 93 is installed on the water circulation pipe 92, so that water in the raw water tank 1 can be obtained in the water circulation pipe 92, and the water in the water circulation pipe 92 circularly flows under the action of the second water circulation pump 93; wherein, the heat exchange assembly 94 includes a first coil 941 and a second coil 942, the first coil 941 is integrally disposed on the cooling water pipe 8, and the second coil 942 is integrally disposed on the circulating water pipe 92, so that the circulating water in the cooling water pipe 8 can flow in the first coil 941, and the water in the circulating water pipe 92 can flow in the second coil 942; meanwhile, the first coil 941 and the second coil 942 are both spiral, wherein the first coil 941 and the second coil 942 are distributed in a staggered manner, and the first coil 941 and the second coil 942 are mutually abutted.

The principle is as follows: when heat of the heat release end of the first TEC semiconductor refrigerator 7 needs to be dissipated, the heat release end of the first TEC semiconductor refrigerator 7 is embedded into the cooling water pipe 8, so that the heat of the heat release end of the first TEC semiconductor refrigerator 7 enters the circulating water, and the temperature of the circulating water can rise due to the fact that the circulating water obtains the heat of the heat release end of the first TEC semiconductor refrigerator 7; wherein, the first circulating water pump 91 is used for pushing the circulating water to circulate, and along with the circulation of the circulating water, the circulating water can continuously exchange the temperature with the outside through the pipe wall of the cooling water pipe 8, and at the moment, the temperature of the circulating water can be reduced.

Meanwhile, by utilizing the circulating water pipe 92 connected to the original water tank 1 and the heat exchange assembly 94 between the circulating water pipe 92 and the cooling water pipe 8, wherein the first coil 941 is communicated with the cooling water pipe 8, the second coil 942 is communicated with the circulating water pipe 92, and the first coil 941 and the second coil 942 are staggered and abutted to each other, when water in the first coil 941 and the second coil 942 flows, heat in high-temperature water can be transferred to heat in low-temperature water, thereby realizing the effect of heat transfer; the circulating water in the cooling water pipe 8 obtains the heat of the heat releasing end of the first TEC semiconductor cooler 7, so the temperature of the water in the cooling water pipe 8 is high, and at this time, the water in the second coil 942 can obtain the heat of the water in the cooling water pipe 8, and finally the temperature of the circulating water can be reduced, so that the heat of the heat releasing end of the first TEC semiconductor cooler 7 can be conveniently dissipated.

Simultaneously because first coil 941 and second coil 942 all are the heliciform so length all longer, can make the water in first coil 941 and the second coil 942 carry out more abundant heat exchange after conflicting each other together when first coil 941 and second coil 942, finally can be favorable to the temperature of rapid reduction circulating water to further the convenience dispels the heat to the end heat of giving out heat of first TEC semiconductor cooler 7.

Under the condition of the same cooling time and the same water quantity, the comparison of the final water temperatures obtained after the temperature of the water with the same initial water temperature is reduced by different implementation groups is shown in a table 1.

Meanwhile, the amount of water cooled by different implementing groups within the same cooling time and the same cooling degree is compared in table 2.

Table 1

Table 2

	Duration (h)	Temperature lowering degree (. degree. C.)	Amount of refrigerating water (L)
				Prior Art	1	10	0.2
Example 1	1	10	0.5
				Example 2	1	10	1.2

In the prior art, a fan is independently adopted to dissipate heat of a heat release end of a first TEC semiconductor cooler, and table 1 shows that: when 0.5L of water with the initial water temperature of 25 ℃ is heated for 3 hours, the final water temperature obtained by the prior art is reduced by 5 ℃ to 20 ℃; whereas the final water temperature obtained in example 1 decreased by 13 ℃ to 12 ℃; the final water temperature obtained in example 2 dropped by 18 ℃ to 7 ℃.

As can be seen from table 2: when the water is required to be cooled by 10 ℃ within 1h, the prior art can only cool 0.2L of water, whereas embodiment 1 can cool 0.5L of water, and embodiment 2 can cool 1.2L of water.

At this time, it can be found that: through the technical scheme of embodiments 1 and 2, the heat dissipation of the heat at the heat release end of the first TEC semiconductor cooler can be accelerated, and the heat dissipation efficiency of the heat at the heat release end of the first TEC semiconductor cooler is greatly increased.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (9)

1. The utility model provides a clean quick electronic refrigeration system of long-term for drinking water all-in-one, includes former water tank (1), composite filter element (2) be connected with former water tank (1), be located booster pump (3) between former water tank (1) and composite filter element (2), filter core (4) be connected with composite filter element (2), pure water tank (5) be connected with filter core (4), cold water tank (6) be connected with pure water tank (5), set up first TEC semiconductor cooler (7) on cold water tank (6), be provided with inlet tube (61) be connected with pure water tank (5) on cold water tank (6), outlet pipe (62) that the water after the cooling was discharged, filter core (4) are the RO filter core or receive the filter core, its characterized in that: the thermoelectric cooler further comprises a cooling water pipe (8) in which circulating water is injected and the heat release end of the first TEC semiconductor refrigerator (7) is embedded, and a heat dissipation device (9) used for dissipating heat of the circulating water in the cooling water pipe (8).

2. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 1, wherein: one end of the cooling water pipe (8) is connected with the waste water outlet end of the filtering filter element (4) and the other end is connected with the raw water tank (1).

3. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 2, characterized in that: the heat dissipation device (9) comprises a heat dissipation pipe (901) which is integrally arranged on the cooling water pipe (8) and extends in an S shape, and an air-cooled radiator (902) arranged on the heat dissipation pipe (901).

4. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 1, wherein: the heat dissipation device (9) comprises a first circulating water pump (91) with a water inlet end and a water outlet end respectively connected with two ends of the cooling water pipe (8), a circulating water pipe (92) with two ends communicated with the original water tank (1), a second circulating water pump (93) arranged on the circulating water pipe (92), and a heat exchange assembly (94) arranged between the circulating water pipe (92) and the cooling water pipe (8).

5. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 4, wherein: heat exchange assembly (94) including set up on cooling water pipe (8) and be spiral helicine first coil pipe (941), set up on circulating water pipe (92) and with first coil pipe (941) crisscross second coil pipe (942) that distributes, first coil pipe (941) and second coil pipe (942) conflict each other.

6. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 4, wherein: and the cooling water pipe (8) is also provided with a plurality of second TEC semiconductor refrigerators (81) with heat absorption ends embedded in the cooling water pipe (8).

7. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 6, wherein: and a low-speed cooling fan (811) is arranged on the heat release end of the second TEC semiconductor cooler (81).

8. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 4, wherein: the circulating water in the cooling water pipe (8) is pure water in the pure water tank (5).

9. The long-acting fast electronic refrigeration system for the water purifying and drinking all-in-one machine as claimed in claim 1, wherein: and one end of the water outlet pipe (62) positioned in the cold water tank (6) is positioned at the lower end of the cold water tank (6).

Images