KR101600709B1 - Dehumidifier having thermoelement - Google Patents

Abstract

The present invention relates to a dehumidifier using a thermoelement and, more specifically, to a dehumidifier using a thermoelement which sucks humid air in the air and allows the sucked humid air to penetrate through a cooling sink connected to the thermoelement to condense into condensed water and to discharge the condensed water and, in the meantime, allows cooling of a heat sink connected to the thermoelement smoothly.

Description

{DEHUMIDIFIER HAVING THERMOELEMENT}

The present invention relates to a dehumidifier using a thermoelectric element, and more particularly, to a dehumidifier using a thermoelectric element, more particularly, to suck humid air contained in the air and to condense the condensed humid air while passing through a cooling sink connected to the thermoelectric element, To a dehumidifier using a thermoelectric element to smoothly cool a heat sink connected to a thermoelectric element.

Generally, a dehumidifier refers to a device that sucks indoor air and heats it, cooling the heated air to remove excess moisture, and then discharges it to the room again.

However, in the conventional dehumidifier, since the air to be sucked is heated by the heater and cooled by the refrigerant circulated through the piping, the structure of the dehumidifier is complicated, and it is expensive and difficult to repair in case of failure.

In addition, since the cooling process and the heating process are performed by a mechanical device, there is a problem that noise is large and energy consumption is large.

On the other hand, Korean Patent Registration No. 10-789161 discloses an electronic dehumidifier having a low temperature shutdown function using a thermoelectric element.

However, such a conventional dehumidifier has a problem that the cooling of the heat sink is not smoothly performed, and the life of the product is shortened as well as the damage of the thermoelectric device.

Korean Registered Patent No. 10-789161 (December 28, 2007)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an air conditioner which sucks humid air contained in the air and condensed while passing through a cooling sink connected to the thermoelectric element, It is another object of the present invention to provide a dehumidifier using a thermoelectric element for smoothly cooling a heat sink connected to the thermoelectric element.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an air conditioner comprising: a casing having an inlet through which air flows in from outside and an outlet through which air is introduced; A thermoelectric element located inside the casing and having a heat sink and a cooling sink on the front and rear surfaces, respectively; A suction fan connected to the inlet and sucking air from the outside to the inside of the casing and allowing the heat sink to be primarily cooled by the supplied air; And a cooling means for allowing the heat sink to be secondarily cooled. The air sucked through the suction fan sequentially passes through the heat sink and the cooling sink, is discharged to the outside through the discharge port, And the moisture is condensed while passing through the cooling sink and discharged as condensed water.

The casing according to the present invention comprises: an intermediate casing having upper and lower openings, an inlet formed at a front surface thereof and an outlet formed at a rear surface thereof; An upper casing for blocking an upper portion of the opened intermediate casing; And a lower casing in which a lower portion of the opened intermediate casing is cut off, and a space portion in which an upper portion is opened and in which condensed water is collected inward is formed.

In the intermediate casing according to the present invention, first and second flanges protruding outwardly are formed on the upper and lower sides, and the upper casing has a lower portion that is open to the lower portion, A flange is formed and the upper surface is curved, and the lower casing is formed with a lower flange which is coupled with the second flange to the upper outer side.

The intermediate casing according to the present invention comprises: a first casing in which the inlet port is formed; And a second casing which is symmetrical with respect to the first casing in the forward and backward directions and on which the discharge port is formed, and the first and second casings include a pair of first and second side flanges protruding outward on both sides So that they are mutually contacted.

The casing according to the present invention may further include a branching plate for branching the inside of the intermediate casing in the forward and backward direction and branching to a cooling space where the cooling sink is located and a suction space where the heat sink is located.

The cooling means according to the present invention includes cooling water accommodated in the space portion, and the lower portion of the heat sink is immersed in the cooling water.

The cooling means according to the present invention may include: cooling water accommodated in the space portion; A heat exchange tube in which both ends thereof are opened to form an injection port through which the cooling water is supplied to one end thereof and a discharge port through which the cooling water supplied to the other end thereof is discharged and between which both ends of the heat sink are repeatedly passed in both directions; And a pump which is accommodated in the space and supplies the cooling water to the heat exchange tube so that the cooling water is circulated while being supplied to the injection port and discharged to the space part through the discharge port.

The intermediate casing according to the present invention further includes a support plate for supporting the heat sink, wherein the heat sink is spaced apart from the cooling water accommodated in the space while the lower portion is seated on the support plate.

According to the present invention, humid air contained in air is condensed while passing through a cooling sink connected to a thermoelectric element and discharged as condensed water, thereby effectively removing moisture.

Further, since the heat sink connected to the thermoelectric element can be cooled smoothly, it is possible to prevent breakage of the thermoelectric element which may be generated while the heat sink is raised to a high temperature.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

1 and 2 are perspective views showing a dehumidifier using a thermoelectric device according to the present invention.
3 is a perspective view showing another example of an intermediate casing in a dehumidifier using a thermoelectric device according to the present invention.
FIG. 4 is a perspective view illustrating a state in which the upper casing is opened in FIG. 3. FIG.
5 is an exploded perspective view showing Fig.
6 is a rear perspective view showing another example of the first casing in the dehumidifier using the thermoelectric element according to the present invention.

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

1 to 6, a dehumidifier 1 using a thermoelectric device according to the present invention includes an inlet 11 through which air flows from the outside and a casing 10 through which an outlet 12 through which air is introduced is formed. A suction fan 20 connected to the inlet 11 and sucking air from the outside and supplying the air to the inside of the casing 10; a heat sink 31 located inside the casing 10, And a cooling unit 40 for cooling the heat sink 31. The heat dissipation unit 30 includes a heat dissipating unit 32 and a cooling unit 40 for cooling the heat sink 31. [

Air sucked into the casing 10 through the suction fan 20 is sequentially passed through the heat sink 31 and the cooling sink 32 and is discharged to the outside through the discharge port 12, Moisture contained in the air condenses while passing through the cooling sink 32 and is discharged as condensed water.

That is, it can be understood that the condensed water is condensed and discharged while the moisture contained in the air passing through the cooling sink 32 is cooled to a dew point temperature or lower by the cooling sink 32.

1 and 2, the casing 10 includes an intermediate casing 13 having upper and lower openings, an inlet 11 formed at a front surface thereof and an outlet 12 formed at a rear surface thereof, And an upper casing 14 for blocking the upper portion of the intermediate casing 13 and a lower casing 15 for blocking the lower portion of the opened intermediate casing 13 and collecting condensed water.

The air sucked into the suction fan 20 flows through the inlet 11 and flows into the casing 10 in the forward and backward directions while being discharged toward the outlet 12.

The intermediate casing 13 may be formed in various shapes, but it is most preferable that the intermediate casing 13 has a rectangular shape in which upper and lower portions are opened.

The intermediate casing 13 is formed with first and second flanges 13a and 13b protruding outward at the upper and lower sides and coupled with the upper and lower casings 14 and 15.

2, the intermediate casing 13 includes a first casing 16 in which the inlet port 11 is formed and a second casing 16 in which the outlet port 12 is formed before and after the first casing 16 And the second casing 17.

The first and second flanges 13a and 13b are formed on the upper and lower sides of the first and second casings 16 and 17 with the center portion of the casing 10 as a center.

For example, the first casing 16 has a "C" shape with upper, lower, and rear portions open, and a rear portion of the first and second flanges 13a, 13b is formed thereon.

The second casing 17 has a "C" shape with open top, bottom, and front portions, and a front portion of the first and second flanges 13a, 13b is formed thereon.

As shown in FIGS. 1 and 2, the first and second casings 16 and 17 are connected to each other by overlapping each other, or a pair of first and second casings 16 and 17 protruding outward on both sides thereof as shown in FIGS. The flanges 16a and 17a are formed to be connected to each other.

At this time, the first and second housings 16 and 17 are connected to each other or the pair of first and second side flanges 16a and 17a by the coupling means including bolts, nuts, screws, And the like.

The upper casing 14 has the same shape as the periphery of the intermediate casing 13 and is formed with an upper flange 14a which is opened at the lower portion and is coupled to the first flange 13a at the lower outer side thereof .

The intermediate casing 13 and the upper casing 14 are connected to each other by detachably connecting the first flange 13a and the upper flange 14a by coupling means including bolts, . ≪ / RTI >

The upper casing 14 preferably has a curved surface whose upper surface protrudes upward so that the air flowing into the inlet 11 can flow smoothly toward the outlet 12.

The lower casing 15 has the same shape as the periphery of the intermediate casing 13 and is formed with a space 15a in which the upper portion is opened and the lower portion of the lower casing 15 is trapped inward. A lower flange 15b coupled to the lower flange 13b is formed.

The intermediate casing 13 and the lower casing 15 are connected to each other by detachable means such that the second flange 13b and the lower flange 15b are connected by a coupling means including a bolt, . ≪ / RTI >

The suction fan 20 is driven by external power and is connected to the intermediate casing 13 so as to be located forward or rearward of the inlet 11.

The suction fan 20 is located in front of the heat sink 31. The suction fan 20 sucks outside air in accordance with driving so that the air is brought into contact with the heat sink 31, Can be cooled.

2 or 5, the thermoelectric element 30 is positioned inside the casing 10 such that the front surface thereof faces the suction fan 20, and the front surface of the thermoelectric element 30 is positioned on the front surface thereof, (31), and the cooling sink (32) is connected to the rear surface.

The thermoelectric element 30 has a generally known shape in which an endothermic phenomenon, that is, cooling is performed on the front surface as the power is supplied, and a heat phenomenon, that is, a high temperature, is generated on the rear surface.

The heat sink 31 dissipates the heat generated from the thermoelectric element 30 to prevent the performance of the thermoelectric element 30 from remarkably lowering due to the high temperature and to improve the cooling efficiency.

The heat sink 31 includes a heat radiating plate 33 connected to the front surface of the thermoelectric element 30 and a plurality of radiating fins 34 connected to the heat radiating plate 33.

The plurality of radiating fins 34 have upper and lower end portions and front and rear end portions, respectively, and the rear end thereof is integrally connected to the heat radiating plate 33 and the front end portion thereof is arranged to be spaced apart from each other in the direction of the inflow opening 11 do.

The cooling sink 32 is cooled by an endothermic phenomenon generated in the thermoelectric element 30, and the moisture is cooled to a dew point temperature or less and condensed.

The cooling sink 32 includes a cooling plate 35 connected to the rear surface of the thermoelectric element 30 and a plurality of cooling fins 36 connected to the cooling plate 35.

The front end of the cooling fin 36 is integrally connected to the cooling plate 35 and the rear end of the cooling fin 36 is directed toward the discharge port 12, Respectively.

It is to be understood that the thermoelectric element 30 is located behind the suction fan 20 while the heat sink 31 or the cooling sink 32 is fixed to the casing 10.

The casing 10 is divided into a cooling space 18b in which the cooling sink 32 is located and a suction space 18c in which the heat sink 31 is located by branching the inside of the intermediate casing 13 in the forward and backward directions And a branching plate 18 that branches off.

The branch plate 18 is configured such that the air sucked by the suction fan 20 passes through the suction space 18c and passes through the upper surface of the upper casing 14 to smoothly flow into the cooling space 18b .

The branch plate 18 is provided in the second casing 17 and the hollow 18a through which the cooling sink 32 passes is formed in the forward and backward directions.

The cooling sink 32 is located in the cooling space 18b through the hollow 18a and the heat sink 31 is positioned in the suction space 18c so that the thermoelectric element 30 is positioned in the hollow space 18c, (18a).

The air sucked into the suction fan 20 flows through the inlet 11, the suction space 18c, the upper casing 14, the cooling space 18b, and the cooling sink 32 sequentially The moisture contained in the air is condensed while passing through the cooling sink 32 and falls into the condensed water and is collected in the lower casing 14. [

The cooling means (40) secondarily cools the heat sink (31), which is primarily cooled by the suction fan (20).

The cooling unit 40 includes cooling water 41 accommodated in the space 15a and the cooling water 41 is cooled by the cooling water 41 so that the cooling water 41 is cooled down. .

For example, the heat sink 31 is located below the water surface of the cooling water 41 which is in contact with the bottom of the space 15a or is accommodated in the space 15a.

The cooling water 41 is kept at a temperature lower than that of the heat sink 31 so that the heat generated by the heat sink 31 can not be heated to a predetermined temperature or higher.

Here, it can be understood that the cooling water 41 can maintain the low temperature state while collecting the condensed water at the low temperature state, which is condensed and dropped in the cooling sink 32.

Alternatively, the cooling means 40 may have an injection port 43 through which the cooling water 41 is supplied at one end and a discharge port 44 through which the cooling water 41 supplied at the other end is discharged. A heat exchange tube 42 which is repeatedly passed through the heat sink 31 in both directions and a cooling water pipe 41 which is accommodated in the space portion 15a and supplies the cooling water 41 to the heat exchange pipe 42, And a pump 45 that is supplied to the injection port 43 and discharged to the space portion 15a through the discharge port 44 to be circulated.

Preferably, the heat sink 31 is spaced apart from the cooling water 41 received in the space 15a while being spaced apart from the space 15a.

For this purpose, the intermediate casing 13 may further include a support plate 19 for supporting the heat sink 31 therein, as shown in FIG.

The support plate 19 blocks the lower part of the opened first casing 16 and a through hole 19a through which both ends of the heat exchange pipe 42 pass can be formed.

The pump 45 is driven by receiving power from the outside, and the injection port 43 and the discharge port 44 are connected to each other.

The pump 45 is driven so that the cooling water 41 is supplied to the injection port 43 and circulated through the heat exchange pipe 42 to be discharged into the space 15a through the discharge port 44 .

The heat sink 31 is prevented from being heated to a predetermined temperature or higher while being cooled by the cooling water 41 passing through the heat exchange pipe 42 in accordance with the repeated circulation of the cooling water 41.

Therefore, the dehumidifier 1 using the thermoelectric element can cool the heat sink 31 by the cooling means 40 together with the air sucked by the suction fan 20, so that the heat sink 31 It is possible to prevent the temperature from exceeding a predetermined temperature.

In addition, the dehumidifier 1 using the thermoelectric element can condense the moisture contained in the air while passing through the cooling sink 32 and discharge it as condensed water, thereby maintaining a constant humidity in the room.

It is to be understood that the present invention is not limited to the above-described embodiment, but may be modified and changed without departing from the spirit and scope of the present invention as defined in the appended claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Description of the Related Art [0002]
1: Dehumidifier using thermoelectric element 10: Casing
11: inlet 12: outlet
13: intermediate casing 13a: first flange
13b: second flange 14: upper casing
14a: upper flange 15: lower casing
15a: Space part 15b: Lower flange
16: first casing 16a: first flange
17: second casing 17a: second flange
18: Branch plate 18a: hollow
18b: cooling space 18c: suction space
19: Support plate 19a: Through hole
20: Suction fan 30: Thermoelectric element
31: heat sink 32: cooling sink
33: heat sink 34:
35: cooling plate 36: cooling pin
40: cooling means 41: cooling water
42: heat exchanger tube 43: inlet
44: Outlet port 45: Pump

Claims (8)

A casing having an inlet through which air flows in from the outside and an outlet through which the incoming air is discharged;
A thermoelectric element located inside the casing and having a heat sink and a cooling sink on the front and rear surfaces, respectively;
A suction fan connected to the inlet and sucking air from the outside to the inside of the casing and allowing the heat sink to be primarily cooled by the supplied air;
And cooling means for allowing the heat sink to be secondarily cooled,
The casing includes:
An intermediate casing having an upper portion and a lower portion opened, a front portion formed with the inlet, and a rear portion formed with the outlet;
An upper casing for blocking an upper portion of the opened intermediate casing; And
And a lower casing in which a lower portion of the opened intermediate casing is cut off and a space portion in which an upper portion is opened and in which condensed water is collected inward is formed,
Wherein the cooling means comprises:
Cooling water accommodated in the space portion;
A heat exchange tube in which both ends thereof are opened to form an injection port through which the cooling water is supplied to one end thereof and a discharge port through which the cooling water supplied to the other end thereof is discharged, And
And a pump which is accommodated in the space and supplies the cooling water to the heat exchange tube so that the cooling water is circulated while being supplied to the inlet and discharged to the space through the outlet,
Wherein the air sucked through the suction fan
The heat sink and the cooling sink sequentially, and is discharged to the outside through the outlet,
The moisture contained in the air,
And condensed while passing through the cooling sink, and discharged as condensed water. delete The method according to claim 1,
The intermediate casing includes:
First and second flanges protruding outward are formed on the upper and lower sides,
The upper casing includes:
An upper flange is formed to be coupled with the first flange to a lower outer side thereof opened, and an upper face is curved,
The lower casing includes:
And a lower flange coupled to the second flange is formed on the upper outer side of the dehumidifier. The method of claim 3,
The intermediate casing includes:
A first casing in which the inlet port is formed; And
And a second casing which is symmetrical with respect to the first casing in forward and backward directions and in which the discharge port is formed,
In the first and second casings,
And a pair of first and second side flanges protruding outward are formed on both sides of the dehumidifier. The method according to claim 1,
The casing includes:
Further comprising a branching plate which is branched into the intermediate casing in the forward and backward directions and branches to a cooling space where the cooling sink is located and a suction space where the heat sink is located. delete delete The method according to claim 1,
The intermediate casing includes:
Further comprising a support plate for supporting the heat sink,
The heat sink
And the lower portion is seated on the support plate and separated from the cooling water accommodated in the space portion.

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