KR101136227B1 - Air-conditioner utilized by thermo-electrical module - Google Patents

Abstract

PURPOSE: A cooling-and-heating device using a power saving thermoelectric element is provided to operate a generator after amplifying a velocity of an air flow cooled or heated by a thermoelectric element by an amplifying tube so that power is generated. CONSTITUTION: A cooling-and-heating device comprises a chamber(1), a blowing fan(3), a thermoelectric element(5), a first heat conduction pipe(9), a second heat conduction pipe(11), a cooling pipe(13), a heating pipe(15), a first connection pipe(17), a second connection pipe(19), an amplifying tube(21), a first converting valve(23), a second converting valve(25), a power generation fan(27), a generator(29), and a storage battery(31). The blowing fan inhales the outdoor air to the chamber. The thermoelectric element comprises a cooling unit(6) cooled by the electricity and a heating unit(8) radiating heat by the electricity. The first heat conduction pipe is connected to the cooling unit, thereby being cooled. The second heat conduction pipe is connected to the heating unit, thereby being heated. The discharged air cooled in the cooling pipe is sprayed to the heating unit of the thermoelectric element, thereby flowing into the second heat conduction pipe. The discharged air heated in the heating pipe is sprayed to the cooling unit of the thermoelectric element, thereby flowing into the first heat conduction pipe. The amplifying tube amplifies the velocity of an air flow and the air flows into the amplifying tube from the first and second connection pipes. The first converting valve controls an amount of the air sent to the heating unit and amplifying tube by being guided from the first connection pipe.

Description

Air-conditioning equipment using thermoelectric element {Air-conditioner utilized by thermo-electrical module}

The present invention relates to a cooling and heating device using a thermoelectric element, and more particularly, to cooling and heating using a power-saving thermoelectric element capable of cooling and heating at low power by recovering energy by rotating a power generation fan to air discharged by cooling or heating by a thermoelectric element. It is an object to provide a device.

Conventional air conditioning apparatus using a thermoelectric element is disclosed in Patent No. 10-0403155. In a conventional heating and cooling device disclosed in Korean Patent No. 10-0403155, a heat pipe is continuously installed in a vertical direction on a plurality of horizontal heat sinks, and a heat conductor is formed on upper and lower ends of the heat pipe, and the predetermined heat is applied from the front of the heat pipe. An airflow generator consisting of a blower fan that blows the airflow of the air, a chamber installed on the upper and lower sides of the heat conductor, and an antifreeze circulation consisting of a circulation pipe and a circulation pump connected between the chambers to circulate the antifreeze in the chamber. And a plurality of thermoelectric elements interposed between the thermal conductor and the chamber to apply cold air or heat by a predetermined power operation. Thus, heating and cooling devices are implemented using thermoelectric elements and heat pipes.

In the conventional heating and cooling device using a thermoelectric element, a heating device and a cooling device are implemented by supplying electricity to a thermoelectric element by using a heat generating part or a cooling part of the thermoelectric element. In this case, since a lot of electricity is consumed to drive the thermoelectric element for cooling or heating, there is a problem that a maintenance cost is required to maintain the cooling and heating device.

The present invention is intended to solve the above problems. An object of the present invention is to provide a power-saving cooling and heating device using a thermoelectric element that can implement a cooling and heating device at low power.

Heating and cooling device using a thermoelectric element according to the present invention is a chamber, a blowing fan, a thermoelectric element, a first heat conduction tube, a second heat conduction tube, a cooling tube, a heating tube, a first connecting tube, a second And a connecting pipe, an amplifying pipe, a first switching valve, a second switching valve, a power generating fan, a generator, a storage battery, a water storage tank, and injection means. The blowing fan sucks outside air into the chamber. The thermoelectric element is installed in the chamber including a cooling unit that is cooled by electricity and a heat generating unit that generates heat. The first heat conducting tube is connected to the cooling unit of the thermoelectric element and cooled. The second heat conductive tube is connected to the heat generating portion of the thermoelectric element and heated. The cooling pipe is connected to circulate a part of the air sucked by the blowing fan around the first heat conducting pipe to cool a part of the air. The heating tube is connected to circulate the remainder of the air sucked by the blowing fan around the second heat conductive tube to heat the remainder of the air. The first connecting pipe is connected to be introduced into the second heat conductive pipe is injected into the heat generating portion of the thermoelectric element by guiding the air discharged from the cooling pipe. The second connection pipe is connected to be introduced into the first heat conducting pipe is injected into the cooling unit of the thermoelectric element by guiding the air discharged from the heating pipe. The amplification pipe is formed with a wide inlet portion and a narrow outlet portion so as to amplify the flow rate of air, and the first connecting tube and the second connecting tube so that air can be introduced from the first connecting tube and the second connecting tube. Is connected to. The first switching valve is installed in the first connecting pipe so as to adjust the amount of air guided by the first connecting pipe to the heat generating portion and the amplifying pipe. The second switching valve is installed in the second connecting pipe so as to adjust the amount of air guided by the second connecting pipe to the cooling unit and the amplifying pipe. The power fan is rotated by air discharged from the amplification pipe. The generator is operated by the power generating fan to produce electricity. The battery stores electricity generated by the generator and operates the thermoelectric element.

In addition, the air-conditioning device using the thermoelectric element preferably further comprises a water storage tank and the injection means. The water storage tank stores the water falling from the cooling unit of the thermoelectric element. The spraying means injects water stored in the water storage tank and sends the water to the amplifying pipe.

In addition, the cooling and heating device using the thermoelectric element is opened so that only a portion of the air guided by the first connecting pipe is guided to the heat generating portion when the cooling, the second switching valve is the second connecting pipe It is preferable that all of the guided air is opened to be guided to the cooling unit. In this case, when heating, the first switching valve is opened so that all the air guided from the first connecting pipe is guided to the heat generating part, and the second switching valve is a part of the air guided from the second connecting pipe to the cooling part. Open to be guided.

In addition, it is preferable that the air conditioning and heating device using the thermoelectric element further includes an adapter. The adapter supplies electricity to the storage battery. In this case, the blower fan operates by receiving electricity from the battery.

According to the present invention, electricity can be produced by amplifying a flow rate of air heated or cooled by a thermoelectric element with an amplifying tube and then driving a generator. And since the electricity produced to drive the thermoelectric element can be used, it is possible to drive the cooling and heating device with less power.

1 is a conceptual diagram of an embodiment of a heating and cooling device using a thermoelectric device according to the present invention.

Referring to Figure 1 will be described an embodiment of a heating and cooling device using a thermoelectric device according to the present invention.

The air conditioning and heating device using the thermoelectric device according to the present invention is a chamber (1), a blowing fan (3), a thermoelectric element (5), a first heat conductive tube (9), a second heat conductive tube (11), cooling Tube 13, heating tube 15, first connecting tube 17, second connecting tube 19, amplifying tube 21, first switching valve 23, second switching The valve 25, the power generating fan 27, the generator 29, the storage battery 31, the water storage tank 33, the injection means 35, and the adapter 37 are included.

The blowing fan 3 serves to suck outside air into the chamber 1.

The thermoelectric element 5 is installed in the chamber 1, and includes a cooling unit 6 and a heat generating unit 8. When electricity is supplied to the thermoelectric element 5, the cooling unit 6 is cooled, and the heat generating unit 8 is heated. The chamber 1 is divided into two by the thermoelectric element 5, half of the air sucked by the blower fan 3 is supplied to the upper portion of the chamber 1 having the heat generating portion 8 and the other half is cooled ( 6) is supplied to the bottom of the chamber (1).

The first heat conducting pipe 9 is connected to the cooling unit 6 and cooled by the cooling unit 6. The second heat conductive pipe 11 is connected to the heat generating portion 8 and heated by the heat generating portion 8.

The cooling pipe 13 is connected to allow the air sucked in to circulate around the first heat conducting pipe 9 so as to cool a part of the air sucked in the blowing fan 3. The cooling tube 13 spirally surrounds the first heat conducting tube 9 so that the air flowing into the cooling tube 13 is cooled by the first heat conducting tube 9. Thus, the air supplied to the lower portion of the chamber 1 flows into the cooling tube 13 and is cooled by the first heat conducting tube 9.

The heating tube 15 is connected to allow the sucked air to be circulated around the second heat conductive pipe 11 to heat the rest of the air sucked from the blowing fan 3. The heating tube 15 spirally surrounds the second heat conductive tube 11 to allow the air flowing into the heating tube 15 to be heated by the second heat conductive tube 11. Thus, the air supplied to the upper portion of the chamber 1 flows into the heating tube 15 and is heated by the second heat conductive tube 9.

That is, half of the air introduced by the blower fan 3 flows into the cooling tube 13, circulates around the first heat conducting tube 9, and is cooled. The other half flows into the heating tube 15, and the second heat conduction. It is heated by circulating around the tube 11.

The first connecting pipe 17 is connected to the air discharged by the cooling tube 13 to be discharged to the heat generating unit 8 of the thermoelectric element 5 to be introduced into the heating tube 15. That is, the first connecting pipe 17 extends from the outlet of the cooling pipe 13 so that air can be injected into the heat generating part 8 of the thermoelectric element 5. Air injected into the heat generating unit 8 cools the heat generating unit 8 and then flows into the heating tube 15.

The second connection pipe 19 is connected to be introduced into the cooling pipe 13 by being injected into the cooling unit 6 of the thermoelectric element 5 by guiding the air discharged from the heating pipe 15. That is, the second connecting pipe 19 extends from the outlet of the heating pipe 15 so that air can be injected into the cooling unit 6 of the thermoelectric element 5. The air injected into the cooling unit 6 flows into the cooling tube 13 after heating the cooling unit 6.

The amplification pipe 21 serves to amplify the flow rate of air because the inlet part and the outlet part are narrow, and the first connector pipe 17 allows the air to flow in from the first connector pipe 17 and the second connector pipe 19. ) And the second connector 19. That is, the first connecting tube 17 and the second connecting tube 19 are both connected to the inlet of the amplifying tube 21.

The first switching valve 23 is installed in the first connecting pipe 17 so as to adjust the amount of air guided by the first connecting pipe 17 to the heat generating section 8 and the amplifying pipe 21. The first switching valve 23 is opened to send 70 to 90% of the air guided by the first connecting pipe 17 to the amplifying pipe 21 and to send only the rest to the heating unit 8 during cooling. And when heating, all the air guided by the first connecting pipe 17 is opened to send to the heat generating section (8).

The second switching valve 25 is installed in the second connecting pipe 19 so as to adjust the amount of air guided by the second connecting pipe 19 to the cooling unit 6 and the amplifying pipe 21. The second switching valve 25 is opened to send all the air guided by the second connecting pipe 17 to the cooling unit 6 at the time of cooling. And during heating, 70-90% of the air guided by the second connecting pipe 19 is sent to the amplifying pipe 21 and only the rest is opened to send to the cooling unit (6). Air introduced into the amplifying pipe 21 through the first switching valve 23 or the second switching valve 25 is amplified and discharged with a flow rate.

The power generating fan 27 is installed to rotate with the air discharged from the amplifying pipe 21.

The generator 29 operates by the power generating fan 27 to produce electricity.

The battery 31 stores electricity generated by the generator 29, and supplies electricity to operate the thermoelectric element 5 and the blower fan 3.

The water storage tank 33 stores moisture falling from the cooling unit 6 of the thermoelectric element 5.

The injection means 35 sprays the water stored in the water storage tank 33 and sends it to the amplification pipe. As the injection means 35, an ultrasonic wave exciter or the like may be used.

The adapter 37 supplies electricity to the storage battery 31. Since the electricity supplied by the generator 29 alone may not be sufficient to drive the thermoelectric element 5 and the blower fan 3, the adapter 37 may be connected to supply electricity to the storage battery 31.

In the case of cooling using the present embodiment, air is introduced into the chamber 1 by the blowing fan 3. The air introduced into the chamber 1 is introduced into the heat generating part 8 of the upper half and the cooling part 6 of the lower half. When electric power is supplied by the storage battery 31, the thermoelectric element 5 cools the cooling unit 6, and the heat generating unit 8 is heated. The first heat conducting tube 9 is then cooled and the second heat conducting tube 11 is heated. The air introduced into the lower portion of the chamber 1 flows into the cooling tube 13 and is cooled by the first heat conductive tube 9 while circulating outside the first heat conductive tube 9. Air cooled in the cooling pipe 13 is supplied to the first connecting pipe (17). In the case of cooling, the first switching valve 23 is partially opened so that 70 to 90% of the air is supplied to the amplifying tube 21, and the rest is injected to the heat generating part 8 of the thermoelectric element 5. In the thermoelectric element 5, the temperature difference between the heat generating portion 8 and the cooling portion 6 is constant. Therefore, if the temperature of the heat generating section 8 rises too high, the temperature of the cooling section 6 does not drop low. In this case, the efficiency of cooling falls. Thus, in order to lower the temperature of the heat generating unit 8, a part of the air supplied from the first connecting pipe 17 is injected into the heat generating unit 8 of the thermoelectric element 5. When the temperature of the heat generating unit 8 drops, the temperature of the cooling unit 6 may be lowered.

The air supplied to the upper portion of the chamber 1 flows into the heating tube 15 together with the air injected from the first connecting tube 17 and circulates outside of the second heat conductive tube 11 while the second heat conductive tube 9 Heated by). The air heated in the heating tube 15 is supplied to the second connecting tube 19. In this case, the second switching valve 23 is completely opened so that all air is injected into the cooling unit 6 of the thermoelectric element 5. Air injected into the cooling unit 6 of the thermoelectric element 5 is introduced into the cooling tube 13 and cooled.

Therefore, the air introduced by the blowing fan 3 is cooled while passing through the cooling tube 13 and supplied to the amplifying tube 21. The air supplied to the amplifying pipe 21 is amplified in flow velocity and supplied to the power generating fan 27. Then, the power fan 27 rotates to drive the generator 29 to produce electricity. The produced electricity is stored in the battery 31 and used to drive the thermoelectric element 5 and the blower fan 3. On the other hand, the cooled air rotating the power fan 27 is discharged to the outside serves as a cooling device.

In the case of heating using the present embodiment, the air is introduced into the chamber 1 by the blowing fan 3. The air introduced into the lower portion of the chamber 1 flows into the cooling tube 13 and is cooled by the first heat conductive tube 9 while circulating outside the first heat conductive tube 9. Air cooled in the cooling pipe 13 is supplied to the first connecting pipe (17). In the case of heating, the first switching valve 23 is open to the mother part and all air is injected to the heat generating part 8 of the thermoelectric element 5.

The air supplied to the upper portion of the chamber 1 and the air injected from the first connecting tube 17 flow into the heating tube 15 and circulate outside of the second heat conductive tube 11. It is then heated by the second heat conducting tube 9. The air heated in the heating tube 15 is supplied to the second connecting tube 19. In this case, the second switching valve 23 is partially opened so that 70 to 90% of the air is supplied to the amplifying tube 21, and the rest is injected to the cooling unit 6 of the thermoelectric element 5.

On the other hand, when the temperature of the cooling unit 6 drops to a low temperature, dropping occurs in the cooling unit 6 by moisture contained in the air. If a buildup occurs, the heating efficiency of the heating system is reduced. In the present embodiment, even if the dropping occurs in the cooling unit 6, part of the air heated by the heating tube 15 is injected into the cooling unit 6 through the second connecting pipe 19, so that the dropping of the cooling unit 6 Remove it. At this time, the water removed is dropped into the water storage tank (33). Water stored in the water storage tank 33 is sprayed into the amplifying pipe 21 by the spraying means 35.

Therefore, the air introduced by the blowing fan 3 is heated while passing through the heating tube 15 and is supplied to the amplifying tube 21. The air supplied to the amplifying pipe 21 is amplified in flow velocity and supplied to the power generating fan 27. Then, the power fan 27 rotates to drive the generator 29 to produce electricity. The produced electricity is stored in the battery 31 and used to drive the thermoelectric element 5 and the blower fan 3. On the other hand, the heated air rotated by the power fan 27 is discharged to the outside serves as a heating device.

Therefore, in the present embodiment, by using the air cooled or heated air to drive the power generating fan 27 to produce electricity can be operated at a low power, it can be prevented from falling.

1 chamber 3: blower fan
5: thermoelectric element 6: cooling unit
8: heat generating portion 9: first heat conducting tube
11: second heat conduction pipe 13: cooling pipe
15 heating tube 17 first connecting tube
19: second connector 21: amplification tube
23: first switching valve 25: second switching valve
27: fan for power generation 29: generator
31 storage battery 33 water storage tank
35: injection means 37: adapter

Claims (4)

Chamber,
A blowing fan for sucking outside air into the chamber,
A thermoelectric element installed in the chamber and having a cooling unit that is cooled by electricity and a heat generating unit that generates heat;
A first heat conduction pipe connected to the cooling unit of the thermoelectric element and cooled;
A second heat conductive pipe connected to a heat generating portion of the thermo element and heated;
A cooling pipe connected to circulate a part of the air sucked by the blowing fan around the first heat conducting pipe to cool a part of the air;
A heating tube connected to circulate the remainder of the air sucked by the blowing fan around the second heat conductive tube to heat the rest of the air;
A first connecting pipe connected to the air cooled by the cooling pipe and discharged to the heat generating part of the thermoelectric element to be introduced into the second heat conductive pipe;
A second connecting tube connected to the air discharged by being heated in the heating tube and injected into the cooling unit of the thermoelectric element to be introduced into the first thermal conductive tube;
The inlet portion is wide and the outlet portion is formed narrow to amplify the flow rate of air, and the amplification tube connected to the first connecting tube and the second connecting tube so that air can be introduced from the first connecting tube and the second connecting tube. and,
A first switching valve installed in the first connecting pipe so as to adjust an amount of air guided by the first connecting pipe to the heating unit and the amplifying pipe;
A second switching valve installed in the second connecting pipe so as to adjust the amount of air guided by the second connecting pipe to the cooling unit and the amplifying pipe;
A power generation fan for rotating with air discharged from the amplification pipe,
A generator for producing electricity by operating by the power fan;
And a storage battery for storing electricity generated by the generator and operating the thermoelectric device. The method of claim 1,
A water storage tank for storing moisture falling from the cooling unit of the thermoelectric element,
And heating means for injecting water stored in the water storage tank and sending the water to the amplifying tube. The method of claim 2,
When cooling, the first switching valve is opened so that only a part of the air guided by the first connecting pipe is guided to the heat generating part, and the second switching valve is configured to guide all of the air guided by the second connecting pipe to the cooling part. Open,
When heating, the first switching valve is opened so that all the air guided from the first connecting pipe is guided to the heat generating part, and the second switching valve is configured so that only a part of the air guided from the second connecting pipe is guided to the cooling unit. Heating and cooling device using a thermoelectric element, characterized in that the opening. The method of claim 3,
It further comprises an adapter for supplying electricity to the storage battery,
The blowing fan is a heating and cooling device using a thermoelectric element, characterized in that operated by receiving electricity from the storage battery.

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