KR102036926B1 - A Cooling Device Using ThermoelectricElement - Google Patents

Abstract

The present invention relates to a cooling apparatus using a thermoelectric element, and in particular, the purified and cooled water is not stored in the tank, but can be obtained by direct water, while ensuring the amount of water as well as appropriately control the cooling temperature.
To this end, in the present invention, the thermoelectric element is radiated in a water-cooled manner, and in order to obtain a coolant that can be directly consumed by drinking water, the cooling water is used as a refrigerant in the drinking water cooling tank and a straight pipe is buried in the drinking water cooling tank so that the purified water flowing through the straight pipe is drinkable. Heat exchange with water is to ensure a sufficient amount of water as well as to obtain a drinkable coolant as direct water.

Description

Cooling device using thermoelectric element {A Cooling Device Using ThermoelectricElement}

The present invention relates to a cooling apparatus using a thermoelectric element, and in particular, the purified and cooled water is not stored in the tank but can be obtained by direct water, while ensuring the amount of water as well as appropriately control the cooling temperature.

Currently, the drinking water cooled in the water purifier is generally stored in a reservoir equipped with a cooling means (freezing cycle), so that the drinking water is discharged through the outlet from the reservoir when drinking. The water stored in the reservoir may be contaminated. The problem is that the cooling temperature of the cooled drinking water stored in the reservoir is lowered in the case of continuous discharge is to obtain the cooling water in a direct manner without using the reservoir in recent years.

Such direct water is generally used thermoelectric element, but most of these methods have been proposed to circulate the purified water to the surface of the thermoelectric element to cool, but this method is less practical and low efficiency of the thermoelectric element, and also thermoelectric element Since the heat generated from the heat dissipation will not have many problems in practical use.

In addition, the advantage of using a thermoelectric element is that it can help to improve the environment by not using a compressor to form a refrigeration cycle, and also has the advantage of using in a narrow space because there is little noise generated during use, but the problem of these Most of the heat dissipation method is air-cooled, so there is a disadvantage in that a fan for heat dissipation must be operated.

Therefore, the present invention is to solve the conventional problems that may occur when using a thermoelectric element and to obtain the temperature of the cooled drinking water in a desired state.

To this end, in the present invention, the thermoelectric element is radiated in a water-cooled manner, and in order to obtain a drinkable drinking water with direct water, the drinking water cooled in the cooling tank is used as the refrigerant, and the coiled pipe is inserted into the cooling tank for coiling. It is to obtain drinking water cooled by flowing the pipes from the top to the bottom, and to secure an adequate amount of water by securing the area by the coiled pipes, as well as to obtain the drinkable coolant as direct water.

In addition, in order to obtain a drinkable coolant as a lower drinkable coolant, the drinkable coolant is formed in a zigzag to allow the flow of the coolant to flow at the bottom of the cooling tank in which the thermoelectric element is in close contact to obtain a lower drinkable coolant.

Therefore, it does not use refrigerant that is harmful to the environment for cooling the drinking water, and it does not use the compressor, so it can help to improve the noise or the environment. In order to obtain drinking water cooled by direct water, cold water can be obtained at the time of water extraction due to close adhesion with the thermoelectric element while ensuring sufficient quantity due to the embedding length of the coiled pipe.

1 is a layout view showing an embodiment of the present invention.
FIG. 2 is an enlarged view of a portion of FIG. 1
Figure 3 is a layout view of another embodiment of the present invention
Figure 3a is an embodiment of the arrangement of the bone of the present invention
4 is an enlarged view of a portion of FIG.
5 is a layout view of a third embodiment of the present invention;
Figure 5a is an embodiment of the arrangement of the bone of Figure 5
Fig. 6 is a detail view of a part in Fig. 5;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, in the configuration of the present invention, a cooling tank 20 for cooling drinking water is located on one side of the thermoelectric element 10, and on the other side, a thermoelectric element for cooling the heat of the thermoelectric element. Cooling tanks 30 are located respectively.

At this time, the thermoelectric element cooling tank 30 for cooling the heat of the thermoelectric element 10 as well as the cooling tank 20 for cooling the drinking water are connected by the connecting means 1 to form a space 2 therebetween. And the thermoelectric element 10 is mounted to the space portion 2, wherein the cooling tanks (20, 30) are all made of a material that is excellent in heat transfer if possible, in the present invention in consideration of formability and thermal conductivity (AL) was used and such a material is just one embodiment, and of course, various materials having excellent heat transfer may be used.

In addition, the cooling tank 20 for cooling the drinking water of the present invention is filled with a cooling water, the cooling water through the thermoelectric element 10 to maintain the temperature of the cooling water to maintain a constant temperature and the cooling tank 20 ) Is mounted on the top of the cooling tank temperature sensor 21 to control the temperature of the cooling water to maintain a constant temperature.

In the present invention, the temperature of the cooling water filled in the cooling tank 20 is to maintain the range of 0 ° C ~ 6 ° C before freezing, in this state the cooling tank 20 to be cooled by heat exchange while drinking water flows inside. It is to be provided with a pipe 40 coiled to be.

In addition, when the drinking water flows inside the coiled pipe 40 is to flow from the top of the coiled pipe 40 to the bottom, the coiled pipe 40 is wound a predetermined number of times from the top It is to be gradually cooled by the cooling water of the cooling tank 20 while flowing to the bottom.

In addition, when water is discharged to the outlet 51 for drinking of the drinking water cooled through the coiled pipe 40, the water is quickly discharged by connecting to the straight pipe 50 from the lower side of the coiled pipe 40 to the upper side. It is easy to do so, and when discharged, the change in temperature of cold drinking water is least likely to occur.

The coiled pipe 40 in the present invention was used as a stainless pipe and the temperature of the potable drinking water flowing inside the coiled pipe 40 is to maintain 5 ℃ ~ 10 ℃.

In addition, the coiled pipe 40 is made in the form of a continuous coiling is connected to the drinking water flows from the top to the bottom while having excellent flowability by natural convection by the coolant filled in the cooling tank 20 Gradual cooling will be achieved.

In the present invention, a plurality of thermoelectric elements 10 may be provided, and each of them may be turned on and off, thereby selectively or partially operating the thermoelectric element 10 so that the coiled pipe ( It is possible to maintain a constant temperature of the drinking water flowing through the inside of 40) and to be able to maintain the temperature of the cooling water filled in the cooling tank 20.

This operation allows the temperature sensor 21 to measure the cooling water temperature in the cooling tank 20 to control the cooling capacity of the thermoelectric element 10 to selectively obtain cool drinking water of a desired temperature. Of course it can be used.

In the present invention, when water is discharged to drink the cooled drinking water as described above, by connecting the straight pipe 50 at the bottom of the coiled pipe 40 located in the cooling tank so that the water can be discharged from the top of the straight pipe 50. The outlet port 51 is formed so that the cold state of the direct water can be stably maintained during continuous discharge.

At this time, when the temperature of the cooling water filled in the cooling tank 20 is higher than the set temperature, the outlet 51 for exiting the cold drinking water is blocked, and the drinking water cooled in the straight pipe 50 is returned to the cooling tank 20. By being sent to the sphere 22 it is possible to rapidly lower the cooling water temperature of the cooling tank (20).

Such a changeover is possible by the valve V mounted on the outlet 51 and these valves V are automatically controlled by the electromagnetic valve.

In addition, such a control method is that a variety of known methods can be used, so that the detailed description is to be described and such a bank is to be able to be installed integrally or separated at the outlet.

As described above, in the present invention, the cooling water supplied to the cooling tank 20 supplies the cooled drinking water flowing through the coiled pipe 40 heat exchanged in the cooling tank 20 to supply the cooled drinking water of the cooling tank 20. You can drop the temperature quickly.

In addition, in the case of discarding the cooling water used in the cooling tank 20 in the thermoelectric element cooling tank 30 for cooling the thermoelectric element 10, the cooling efficiency of the thermoelectric element 10 is excellent. You can do it.

In the present invention, when there is much difference between the temperature of the lower part and the upper part of the cooling water filled in the cooling tank 20 having a predetermined area, the water is returned by using the circulation pump 60 between the lower part and the upper part of the cooling tank 20. By circulating at a predetermined time interval with the sphere 22, the cold cooling water in proximity to the thermoelectric element 10 is introduced into the upper portion of the cooling tank 20 so that natural convection occurs due to the specific gravity of the water. Cooling of the potable drinking water flowing into the interior of 40) can be easily achieved to the desired temperature.

5 and 6 illustrate an embodiment for further lowering the cooling temperature of the potable drinking water flowing into the coiled pipe of the present invention before the water is discharged, and is provided on the bottom surface of the cooling tank 20. In order to generate heat exchange directly with the thermoelectric element 10 mounted at the lower end of the cooling tank 20 in only one of the thermoelectric elements, the cooling fins 23 upright at a predetermined height are provided with a zigzag flow path 24. Formed bone 25 is formed, the upper surface of the bone 25 to be sealed with a sealing plate 26 excellent in heat transfer, and the inlet of the bone 25 formed in the form of the cooling fin 23 is coiled By connecting the extension pipe 41 extending from the lower end of the pipe 40 to induce direct contact with the thermoelectric element before the drinking water cooled in the coiled pipe 40 is discharged through the straight pipe 50 The temperature of drinking water It will be more cooled momentarily.

In this case, the extension pipe 41 is positioned at the top or bottom of the cooling tank 20 so as not to damage the cooling fin 23 formed at the bottom of the cooling tank 20. The cooling fin 23 is shown in FIG. As shown is to be formed so as not to be in close contact with the upper and lower sides of the cooling tank (20).

3 and 4 show another embodiment for lowering the cooling temperature of the outlet 51 of the potable drinking water of the present invention to the lowest temperature. The cooling fins 23, which are upright at a predetermined height, form a valley 25 formed with a zigzag flow path 24 in order to have excellent heat exchange with a thermoelectric element mounted at a lower end thereof. The upper surface of the valley 25, that is, the upper surface of the cooling fin 23 is covered with a sealing plate 26 having excellent heat transfer to be sealed, and the pipe 25 coiled at the inlet of the valley 25 formed in the form of the cooling fin 23. By connecting the extension pipe 41 extending from the lower end of the 40 to induce direct contact with the thermoelectric element 10 before the drinking water cooled in the coiled pipe 40 is discharged through the straight pipe 50. Instantly cool down the temperature of drinking water It will be done.

In this case, the connection pipe 41 may directly connect the tip of the lower end of the coiled pipe 40, and is coiled in a state in which the inlet 26a and the outlet 26b are formed on the sealing plate 26. The lower end of the pipe 40 is connected to the inlet, and the straight pipe 50 for water discharge is to be connected to the outlet.

In addition, in order to cool down the heat generated by the thermoelectric element 10 in the thermoelectric element cooling tank 30, the purified water is used as a coolant using the purified water remaining in the water purification system. The temperature sensor in the thermoelectric element cooling tank 30 is sensed by the temperature sensor 31 so that the tank 30 is introduced into the tank 30, and the coolant having a lower temperature from the outside is additionally supplied when the temperature of the coolant is higher than a predetermined temperature. In order to maintain the most appropriate state regardless of the external temperature change by water cooling the heat radiation of the thermoelectric element 10.

In the present invention, the coolant having a lower temperature additionally supplied to the thermoelectric element cooling tank 30 is lower from the outside when the coolant temperature in the thermoelectric element cooling tank 30 for cooling the thermoelectric element 10 becomes 60 ° C. or higher. By supplying the cooling water having a temperature to confirm that the cooling efficiency of the most excellent thermoelectric element 10 is excellent.

In the present invention, the outside of the cooling tank 20 is to be wrapped with a warming agent (not shown) if possible so that the cold air is maintained for a long time and the thermoelectric element cooling tank 30 to open to allow heat radiation by external air. will be.

In addition, the cooling tank 20 and the thermoelectric element cooling tank 30 are formed so that the cooling fins upright to excellent cooling efficiency.

In the present invention, when the drinking water cooled through the coiled pipe 40 is discharged to the outlet 51 through the straight pipe 50, all the acidic water discharged to obtain the discharge water generated in the electrolysis process, that is, weak alkaline water and When the discharged water, such as strong alkaline water, is supplied to the thermoelectric element cooling tank 30 and the drinking water is not used, that is, when the cooled drinking water is not discharged, the coolant supplied to the thermoelectric element cooling tank 30 is an electrolytic cell for electrolysis. All coarse water is supplied to the thermoelectric cooling tank, where the electrolytic cell is not electrolyzed.

10: thermoelectric element
20: cooling tank
30: thermoelectric element cooling tank
40: coiled piping
50: intuitive 51: outlet
60: circulating pump

Claims (5)

The cooling tank is in close contact with one side of the thermoelectric element, and the cooling tank and the thermoelectric element cooling tank are connected by the connecting means to form a space portion inside the connecting means in order to closely contact the thermoelectric element cooling tank.
The cooling tank is provided with a pipe coiled in the state where the cooling water is filled and cooled while exchanging drinking water from the top to the bottom,
Cooled drinking water is cold water is discharged to the outlet connected to the straight pipe located in the cooling tank,
Cooling water filled in the cooling tank is circulated from the bottom to the top by the circulation pump to maintain the temperature,
When the drinking water cooled by the coiled pipe embedded in the cooling tank is discharged to the outlet through the straight pipe, the cooling water discharged by the valve can be discharged drinkingly or supplied to the return port as the cooling water of the cooling tank. Cooling device using a thermoelectric element. delete The method of claim 1,
A plurality of thermoelectric elements mounted in the space portion of the cooling tank and the thermoelectric element cooling tank are provided, and a zigzag flow path is provided on the rear surface of the bottom of the cooling tank by the cooling fins as an upper layer of any one or all of the thermoelectric elements. The corrugated pipe is located in the interior of the cooling tank and is connected to one end of the sealing plate, and the straight pipe is connected to the other end, so that the coolant water cooled down to the outlet through the straight pipe is formed. Cooling device using a thermoelectric element is made of water. delete delete

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