KR100298131B1 - Cooler using thermoelectric element - Google Patents

Abstract

The present invention relates to a air conditioner (commonly known as an air conditioner) capable of supplying cold air into a building interior using air or water as a refrigerant without using a compression method of a compressor.

The present invention, the heat absorbing core 40, the first heat exchanger 50, the auxiliary duct 60, the heat dissipation core 70, the second heat exchanger 80, the water tank 90, the cold heat surface Is attached to the outer surface of the first heat exchanger 50 and the heat generating surface is attached to the outer surface of the second heat exchanger 80 is composed of a thermoelectric element 100 that is electrically controlled by the controller 110 As described above, the present invention does not include a compressor and a condenser, so it can be manufactured compactly and lightly, and is easy to post-repair, and does not use expensive parts, thereby reducing manufacturing costs and supplying inexpensively. There is this.

Description

Air conditioner using thermoelectric element

The present invention relates to a cooler using the Peltier effect of the thermoelectric element, and more particularly, to a cooler (commonly known as an air conditioner) that can supply cool air to a building interior using air or water as a refrigerant without using a compression method of a compressor. will be.

In general, an air conditioner is provided with an evaporator, a condenser, a compressor, an expansion valve, and the like, connected to each other by a pipe, and the refrigerant is circulated to cool the indoor air by heat exchange.

As shown in Fig. 1, the principle of the conventional air conditioner is to compress the refrigerant (R-12, etc.) by driving the compressor as follows.

First, the refrigerant gas is sucked and compressed by the compressor 1 and sent to the condenser 2 in a gas state of high temperature and high pressure (about 70 ° C., 15 kgf / cm 2).

The refrigerant sent from the compressor 1 is forcedly cooled to liquefy, and the liquefied refrigerant flows to the expansion valve 3. In the expansion valve (3), the high pressure liquid refrigerant rapidly expands and becomes a refrigerant in a low temperature low pressure fog state and enters the evaporator (4). The refrigerant in the evaporator 4 takes heat away from the surrounding air, becomes a gaseous refrigerant, and enters the compressor 1 again. In this way, the refrigerant is circulated and cooled while repeating the refrigerant cycle.

However, such a conventional air conditioner has to be used with a compressor, which increases manufacturing costs and consumes very high power (kw / day).

In particular, the so-called stand-type air conditioner with a large capacity has to install the condenser outside the building and work with the main body installed in the building, and the piping work is not only costly and inconvenient to move. The use of the refrigerant has a disadvantage in that the cumbersome and economical burden caused by the replenishment of the refrigerant is great.

It is an object of the present invention to use a refrigerant or air that is commonly available in the surroundings without using a compressor, and to have a series of cooling cycles using a thermoelectric element having a Peltier effect, thereby greatly reducing power consumption (kw / day). It is an object of the present invention to provide a cooler that can be supplied with a small amount of refrigerant and can be supplied at low cost.

1 is a block diagram of a cooler for a general cooling cycle.

Figure 2 is a vertical side cross-sectional view showing a configuration of the present invention.

3 is a circuit diagram of the present invention.

Explanation of symbols on the main parts of the drawings

10; Main body 11; Shielding film 12; nozzle

20; Duct 21; Air inlet 22; Air outlet

30; Blower 40; Endothermic core 50; First heat exchanger

51; A first pump 60; Auxiliary duct 61; Air inlet

62; Air outlet 70; Heat dissipation core 71; Cooling fan

80; Second heat exchanger 90; Tank 91; 2nd pump

100; Thermoelectric element

The present invention has been made in view of the above disadvantages, and the air inlet 21 and the air outlet 22 and the duct 20 in the main body 10 to be disposed on the lower side and the upper side of the main body 10 and And a blower (30) installed on the air inlet (21) side of the duct (20) to blow outside air from the air inlet (21) to the air outlet (22). The first heat exchanger 50 installed in the lower portion of the main body 10 by connecting to the heat absorbing core 40 and the heat absorbing core 40 in a pipe so that the water circulates in one direction by the first pump 51. The auxiliary duct 60 communicates with the duct 20 so that the air inlet 61 is located behind the endothermic core 40, and the air duct 62 communicates with the rear of the main body 10. The heat dissipation core 70 provided with the cooling fan 71 in the auxiliary duct 60, and the second row installed under the main body 10. The heat dissipation core 70 and the second heat exchanger 80 are connected to the lower portion of the main body 10 by pipes to allow air or water to circulate in a predetermined direction by the ventilation 80 and the second pump 91. And a water tank (90) for storing and replenishing air or water, and a cold heating surface attached to an outer surface of the first heat exchanger 50, and a heating surface attached to an outer surface of the second heat exchanger 80, It consists of a thermoelectric element 100 electrically controlled by the 110.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 2 is a vertical side cross-sectional view showing the configuration of the present invention, Figure 3 is a circuit configuration diagram of the present invention.

2 and 3, the duct 20 is embedded in the main body 10, and the space between the main body 10 and the duct 20 is filled with a shielding film 11. The air inlet 21 of this duct 20 is located below the main body 10 front side, and the air outlet 22 is located above the main body 10 front side.

The nozzle 12 is normally provided in front of the air outlet 22, and the nozzle 12 is adapted to adjust the direction of the blowing air automatically or manually.

The blower 30 is installed inside the main body 10 to be located at the air inlet 21 side of the duct 20.

The heat absorbing core 40 is installed at the air inlet 21 to be located at the front or rear of the blower 30, and has a structure in which water flows inside and heat exchanges while the air passes.

The first heat exchanger 50 is installed in the lower part of the main body 10, and is connected to the heat absorbing core 40 by a pipe, and the pipe is provided with a first pump 51 to circulate air or water in a predetermined direction. It is.

The auxiliary duct 60 has an air inlet 61 and an air outlet 62. The air inlet 61 is connected in communication with the duct 20 so as to be located at the rear of the heat absorbing core 40. 62 has a structure in communication with the rear of the main body 10. The cross sectional area of the auxiliary duct 60 is about 1/10 of the cross sectional area of the duct 20.

The heat dissipation core 70 is installed in the auxiliary duct 60 and has a structure in which water flows inside and heat exchanges while air passes. The heat dissipation core 70 is provided with a cooling fan 71 to blow a part of the air passing through the duct 20 from the air inlet 61 side of the auxiliary duct 60 toward the air outlet 62. do. That is, part of the cold air passing through the duct 20 is recovered to the auxiliary duct 60 and used to cool the heat dissipation core 70.

The second heat exchanger 80 is installed in the lower portion of the main body 10, and is connected to the heat absorbing core 40 by a pipe and has a structure in which water passes through the inside of the second pump 91.

The water tank 90 is installed in the lower part of the main body 10 and is connected to the heat dissipation core 70 and the second heat exchanger 80 in order to circulate water in a predetermined direction by the second pump 91. The water tank 90 can store water and replenish water as needed.

The thermoelectric element 100 exerts a Peltier effect according to the application of a current. The cold surface of the thermoelectric element 100 is attached to the outer surface of the first heat exchanger 50, and the heat generating surface of the thermoelectric element 100 is second. It is attached to the outer surface of the heat exchanger 80 and is electrically connected to the controller 110.

On the other hand, it is preferable that the first heat exchanger 50 and the second heat exchanger 80 are embedded in a case, and the gap is filled with a shielding film 12 to shield heat.

The controller 110 is mounted on the front surface of the main body 10 using a microcomputer or an integrated circuit, and is provided with various switches for adjusting a functional part such as a power switch, a flow rate control switch, and a temperature control switch.

Reference numeral 120 is a temperature and humidity sensor 120 is installed on the air outlet 22 side of the duct 20 detects the temperature and humidity of the air discharged from the duct 20 to control the voltage according to the resistance value 110 The controller 110 controls each functional unit according to the input signal and the program to maintain the set temperature.

Referring to the operation of the present invention having such a configuration as follows.

As shown in FIG. 2 and FIG. 3, after the power switch is turned on, the air volume control switch and the temperature control switch are operated, including the blower 30 connected to the electric circuit, the first pump 51 and the second pump ( 91 and the cooling fan 71 are driven. Thus, the hot indoor air is introduced into the air inlet 21 of the duct 20 and then discharged to the air outlet 22, and a part of the air passing through the duct 20 passes through the auxiliary duct 60 to the main body 10. Is emitted to the rear. In addition, apart from circulating water in the heat absorbing core 40 and the first heat exchanger 50, the water circulates in the heat dissipating core 70 and the second heat exchanger 80, and is applied to the thermoelectric element 100. Cooling and heat are generated according to the magnitude of current and voltage, respectively.

First, water passing through the first heat exchanger (50) is cooled to low temperature by cold air generated on the cold heat surface of the thermoelectric element (100), and water from the first heat exchanger (50) forms the endothermic core (40). While passing, the temperature is raised by absorbing the heat of indoor air entering the air inlet 21 and the elevated temperature water flows back into the first heat exchanger 50 to repeat the cooling cycle. And the indoor air passing through the heat absorbing core 40 is cooled to cool the room as it is discharged to the air outlet (22).

The water discharged from the water tank 90 passes through the heat dissipation core 70 to the second heat exchanger 80 and is recovered to the water tank 90 again while the water passes through the second heat exchanger 80. The heat generated from the heat dissipation surface of the thermoelectric element 100 is absorbed, and while the water passes through the heat dissipation core 70, the heat is lost by some air passing through the auxiliary duct 60. As a result, the second heat exchanger 80 quickly absorbs the heat dissipated from the heat dissipating surface of the thermoelectric element 100 to increase the Peltier effect, thereby increasing the cooling efficiency.

In Figure 3, the controller 110 is set in the multi-stage rotational speed of the blower 30 in accordance with the operation of the air volume control switch to adjust the amount of air flow into the duct 20, the operation of the temperature control switch Accordingly, the Peltier effect is exerted by controlling the current and voltage applied to the thermoelectric semiconductor to supply cold heat to the water passing through the first heat exchanger 50. In this case, as the resistance value corresponding to the temperature of the air detected by the temperature and humidity sensor 120 is input to the controller 110, the driving speed and timing of the first pump 51 are controlled at an appropriate voltage through the duct 20. It maintains the set temperature by compensating the temperature of the air discharged into the room. For example, when the air discharged from the duct 20 to the room temperature is lower than or equal to the set temperature, the first pump 51 is driven and cool air is supplied to the thermoelectric element 100, and the discharged air reaches the set temperature. When the current is applied to the first pump 51 and the thermoelectric element 100, the temperature of the air supplied to the room is kept constant.

In addition, although the present invention has been described using water as a coolant, air may be used as a coolant or may be used as a warmer as necessary.

As described above, the present invention does not include a compressor and a condenser, so it can be manufactured compactly and lightly, and there is an advantage that the manufacturing cost can be reduced and inexpensively supplied since no expensive parts are used. In addition, the present invention may not only finely adjust the cooling temperature according to the voltage and current control of the thermoelectric element 100 by cooling the refrigerant using the thermoelectric element 100, but also by the thermoelectric element 100. Since it is rapidly cooled, the cooling time to the set temperature is shortened. In addition, the present invention has the advantage that the structure is simple, there is almost no failure, easy to repair after, and easy to replace and replace the refrigerant because water or air is used as the refrigerant. In addition, since the present invention does not use a compressor, power consumption is greatly reduced and thermal efficiency is further improved by applying a second heat exchanger 80 to increase the Peltier effect.

Claims (1)

An air inlet 21, a duct 20 installed so that the air outlet 22 is disposed on the lower side and the upper side of the main body 10, and the air inlet 22 is installed at the air inlet 21 side. In the air conditioner containing the blower 30 which blows to the side, An endothermic core 40 installed at the air inlet 21, A first heat exchanger 50 installed in the lower portion of the main body 10 by connecting the pipe with the heat absorbing core 40 so that the water circulates in one direction by the first pump 51; An auxiliary duct 60 in communication with the duct 20 so that the air inlet 61 is located behind the endothermic core 40, and an air outlet 62 in communication with the rear of the main body 10; A heat dissipation core 70 provided with a cooling fan 71 in the auxiliary duct 60; A second heat exchanger 80 installed below the main body 10 and installed to correspond to the first heat exchanger; Connecting the heat dissipation core 70 and the second heat exchanger 80 with a pipe so as to circulate water in a predetermined direction by the second pump 91 and installing the lower portion of the main body 10 to store and replenish water. Tank for 90, The cold surface is attached to the outer surface of the first heat exchanger 50 and the heat generating surface is attached to the outer surface of the second heat exchanger 80 consisting of a thermoelectric element 100 that is electrically controlled by the controller 110. Cooler using a thermoelectric element characterized in that.