KR20180116679A - Air conditioner using thermoelement module - Google Patents

Abstract

The present invention relates to an air conditioner. More specifically, the present invention relates to the air conditioner, controlling the temperature of a specific space using a thermoelectric module. Disclosed is the air conditioner, comprising: one or more thermoelectric modules (300) having a heat radiation unit and a heat absorption unit; a first heat exchanging unit and a second heat exchanging unit coupled to each of the heat radiation unit and the heat absorption unit of the thermoelectric module (300); and a condensing water storage unit (250) storing condensing water generated when heat is exchanged in the second heat exchanging unit.

Description

[0001] Air conditioner using thermoelement module [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly, to an air conditioner that adjusts a temperature of a specific space using a thermoelectric module.

A thermoelectric module is a module in which a plurality of thermoelectric elements having a Peltier effect, one end of which is heated and the other end of which is endothermic when DC is applied to both ends thereof, are connected in series to form an air conditioner or a heating device Refers to the module used.

When the thermoelectric module is used as an air conditioner such as a cooling device, an air conditioner or the like, a heat dissipating member such as a heat dissipating fin or a heat dissipating block is coupled to the heat absorbing portion or the heat generating portion do. At this time, the heat dissipating member is fixed to the fixing portion with a fastening member such as a bolt and is coupled with the thermoelectric module.

However, the above-mentioned thermoelectric module has a problem that the efficiency of the thermoelectric module decreases as the time for continuous heat absorption and heat radiation becomes longer.

Particularly, there is a problem that the cooling efficiency of the heat absorbing part may be lowered due to the condensed water generated during heat exchange in the heat absorbing part.

In addition, if the generated condensed water flows in a position where various electric parts are installed, it may damage not only electric parts but also various safety problems.

An object of the present invention is to provide an air conditioner capable of effectively removing condensate generated during a cooling process by using ultrasonic waves and improving functionality such as efficiency of removal of condensed water and utilization of humidification .

The present invention has been made in order to achieve the above-mentioned object of the present invention, and it is an object of the present invention to provide a thermoelectric module including at least one thermoelectric module (300) A first heat exchanging part and a second heat exchanging part coupled to the heat radiating part and the heat absorbing part of the thermoelectric module 300; And a condensed water storage part (250) for storing condensed water generated during heat exchange in the second heat exchange part.

The air conditioner may further include a condensate removing unit 700 for removing condensed water stored in the condensed water storage unit 250 using ultrasonic waves.

The condensate reservoir 250 may include a reservoir 254 having an inlet 251 through which condensate flows and at least one outlet 252 through which the spray formed by the condensate remover 700 is discharged have.

The condensate reservoir 250 may be configured to store the condensate stored in the reservoir 254 to prevent the spray formed by the condensate remover 700 from entering the inlet 251. [ And a partition 253 protruding downward from the ceiling of the lower case 254.

The air conditioner includes a second flow path P2 connecting a second air inlet 210 formed in a housing 200 forming a specific space to be cooled and a second air outlet 220, (240) for forming an air flow in the second flow path (P2) so that the heat exchange of the second heat exchange part is performed by the air flow of the second heat transfer part (P2), and the second air flow forming part May include a first spray forming part for spraying the spray formed by the ultrasonic waves into the second flow path (P2) through the inflow part (251).

The first heat exchanging unit includes at least one heat transfer block 510 coupled to the heat dissipating unit of the thermoelectric module 300 and a heat exchange module fixedly coupled to the heat transfer block 510. The heat exchange module includes a heat transfer module A first air flow forming part 550 for generating an air flow to a first flow path P1 connecting the first air inlet 120 formed in the housing where the module 300 is installed and the first air outlet 110, The condensate removing unit 700 may include a second spray forming unit for spraying the spray formed by ultrasonic waves into the first flow path P1 through the discharge port 252 have.

The air conditioner includes a second flow path P2 connecting a second air inlet 210 formed in a housing 200 forming a specific space to be cooled and a second air outlet 220, And a second air flow forming part (240) forming an air flow in the second flow path (P2) so that the heat exchange of the second heat exchange part is performed by an air flow of the second heat exchange part (P2), and the first heat exchanging part The heat exchange module includes at least one heat transfer block 510 coupled to the heat dissipation unit of the thermoelectric module 300 and a heat exchange module fixedly coupled to the heat transfer block 510, The first air flow forming unit 550 generates air flow to the first flow path P1 connecting the first air inlet 120 formed in the housing and the first air outlet 110, The condensate removing unit 700 is connected to the second flow path P2 through the inlet 251, A second spray forming unit for spraying the spray formed by ultrasonic waves into the first flow path (P1) through the discharge port (252) to form a spray so as to flow the spray formed by the wave, Section.

The air conditioner according to the present invention is provided with a condensed water storage unit for storing condensed water generated during heat exchange in a second heat exchange unit where air is cooled, thereby preventing breakage and contamination of the electric parts caused by condensed water, There is an advantage to be able to do.

The air conditioner according to the present invention further includes a condensed water storage unit for storing condensed water generated during heat exchange in the second heat exchange unit for air cooling and further includes a condensed water removing unit for removing condensed water by ultrasonic waves, Thereby providing a convenient maintenance.

Particularly, there is an advantage that the condensation water reservoir can be further provided with a humidification function and a dehumidification function by making it possible to utilize variously such as spray formed by ultrasonic waves, humidification of the surrounding space, and discharge to the outside.

1 is a longitudinal sectional view showing the air conditioner according to the first embodiment of the present invention, viewed in the Y-axis direction.
Fig. 2 is a sectional view of the air conditioner of Fig. 1 viewed in the X-axis direction. Fig.
3 is a longitudinal sectional view showing the air conditioner according to the second embodiment of the present invention, taken in the Y-axis direction.
4 is an enlarged cross-sectional view showing an enlarged view of the condensed water storage portion of FIG.
Fig. 5 is a sectional view of the air conditioner of Fig. 3 viewed in the X-axis direction. Fig.
6 is a longitudinal sectional view showing a modification of the first embodiment of the present invention in the Y axis direction.
Fig. 7 is a sectional view of the air conditioner of Fig. 6 taken in the X-axis direction.
8 is a vertical sectional view showing a modification of the second embodiment of the present invention in the Y-axis direction.
Fig. 9 is a sectional view of the air conditioner of Fig. 8 viewed in the X-axis direction.
10 is an enlarged sectional view showing another embodiment of the condensed water storage portion of FIG.

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

As shown in FIGS. 1 to 10, the air conditioner according to the present invention includes at least one thermoelectric module 300 having a heat dissipation unit and a heat absorption unit. A first heat exchanging part and a second heat exchanging part coupled to the heat radiating part and the heat absorbing part of the thermoelectric module 300; And a condensed water storage part (250) for storing condensed water generated during heat exchange in the second heat exchange part.

The thermoelectric module 300 may have a variety of configurations as long as the thermoelectric module is provided with a heat dissipation unit and a heat absorption unit.

For example, the thermoelectric module 300 includes a pair of substrates, a plurality of thermoelectric elements (not shown) provided between the pair of substrates, a power applying unit connected to the thermoelectric elements (Not shown).

At this time, the substrate may be made of various materials such as metal and ceramics, but it is preferable to use a ceramic material in consideration of thermal expansion.

Here, the pair of substrates functions as a heat dissipation part and a heat absorption part, depending on the arrangement of the thermoelectric elements.

The thermoelectric module 300 is preferably installed in a plurality of units considering cooling or heating capacity such as two or four for convenience of manufacture. In order to prevent a portion other than the power applying portion from being exposed to the outside, Or the like, which are formed in the heat insulating member.

The first heat exchanging unit and the second heat exchanging unit may be coupled to the heat radiating unit and the heat absorbing unit of the thermoelectric module 300, respectively.

The first heat exchanging unit and the second heat exchanging unit are respectively connected to the heat radiating unit and the heat absorbing unit of the thermoelectric module 300 to maximize the heat radiation effect of the heat radiation unit and the heat absorption effect of the heat absorption unit. Do.

At this time, the first heat exchanger may perform heat exchange using a flow of air or heat exchange using a flow of a coolant such as water, and the second heat exchanger may perform heat exchange with the periphery by using the flow of air.

Particularly, the first heat exchanging part and the second heat exchanging part can have various structures according to a heat exchange method.

For example, the first heat exchanging unit and the second heat exchanging unit may include a heat transfer block 510 that is in surface contact with the heat dissipating unit and the heat absorbing unit, respectively; And a heat exchange module fixedly coupled to the heat transfer block 510.

The heat exchange module is fixedly coupled to the heat transfer block 510 to perform heat dissipation or heat absorption by heat exchange with the heat transfer block 510.

Particularly, the heat exchange module may have various structures depending on a circulation type of refrigerant such as water, and a heat exchange type by air flow.

Specifically, the first heat exchanging unit and the second heat exchanging unit may be configured as shown in FIG. 2 of Patent No. 10-1185567.

That is, the heat exchange module may include at least one of a heat pipe and a stack pin fixedly coupled to the heat transfer block 510. In order to increase the heat exchange efficiency, the heat transfer fins may be coupled to the heat pipe and the stack pin.

1, 3 and 6, the second heat exchanger includes a second air inlet 210 connected to the second air outlet 220 and a second air outlet 220 connected to the second air outlet 210 formed in the second housing 200, And the second air flow forming unit 240 installed in the second housing 200 and generating an air flow in the second flow path P2.

Here, heat exchange is performed through the air flow in the second flow path (P2) formed by the second air flow forming part (240) in the heat exchange module constituting the second heat exchange part.

The second flow path (P2) is configured to perform heat exchange by a second air flow forming part (240) installed in the second housing (200) and generating an air flow in the second flow path (P2) .

Here, heat exchange is performed through the air flow in the second flow path (P2) formed by the second air flow forming part (240) in the heat exchange module constituting the second heat exchange part.

The first heat exchanging unit has a structure similar to that of the second heat exchanging unit, and has a structure for exchanging heat by air flow, and includes at least one heat transfer block 510 coupled with the heat dissipating unit of the thermoelectric module 300. And a heat exchange module fixedly coupled to the heat transfer block 510. The heat exchange module includes a first flow path P1 connecting the first air inlet 120 formed in the first housing 100 and the first air outlet 110, The first air flow forming unit 550 generates air flow through the first air flow forming unit 550.

As another example, the first heat exchanger may perform heat exchange by circulation of a heat medium such as water instead of heat exchange by air flow like the second heat exchanger described above.

For example, the first heat exchanging unit may include a heat transfer block 510 coupled to the heat dissipating unit of the thermoelectric module 300 and having a refrigerant passage 520 through which the refrigerant flows; A cooling unit 560 connected to the refrigerant channel and through which the refrigerant flows; And a circulation pump 540 that circulates the cooled refrigerant through the cooling part 560 to the heat transfer block 510.

At this time, the refrigerant is a heat transfer medium that circulates the heat transfer heat exchanger 800 and the heat transfer block 510 and performs heat transfer, and water or the like can be used.

The heat transfer block 510 may have a variety of configurations, such as a refrigerant passage 520, which is coupled to the heat dissipating portion of the thermoelectric module 300 and through which the refrigerant flows.

For example, the heat transfer block 510 can be manufactured by forming a coolant channel 520 inside a block of a material such as aluminum or stainless steel having a high heat transfer rate by drilling, welding, or the like.

The refrigerant passage 520 may be formed in the heat transfer block 510 and may have various structures and arrangements as long as the refrigerant can flow.

For example, the refrigerant passage 520 may be formed in the heat transfer block 510 so as to allow the refrigerant to flow therethrough. In order to increase the heat exchange area of the heat transfer block 510 and to form turbulence, And a plurality of one can be installed.

The circulation pump 540 may be installed at various positions according to the circulation direction of the refrigerant, for circulating the refrigerant between the heat transfer block 510 and the cooling part 560.

The circulation pump 540, the heat transfer block 510, and the cooling unit 560 are connected by one or more refrigerant circulation pipes 530.

The circulation pump 540 is connected to the refrigerant circulation pipe 530 through an inlet and an outlet of the circulation pump 540 so as to prevent the heated refrigerant passing through the heat transfer block 510 and passing through the circulation pump 540, And the coolant outlet 528 and the coolant inlet 529 of the heat transfer block 510 are connected to the coolant outlet port 528 and the coolant inlet port 529, respectively.

The refrigerant circulation pipe 530 may be any tube that can circulate the refrigerant through the circulation pump 540, the heat transfer block 510, and the cooling unit 560.

An electrothermal heat exchanger 800 is additionally provided between the heat transfer block 510 and the cooling section 560 of the refrigerant circulation pipe 530 in order to maximize the effect of preheating before being introduced into the cooling section 560 .

The heat transfer heat exchanger 800 includes a plurality of pipe members through which the refrigerant discharged from the heat transfer block 510 flows and a plurality of pipe members connected to the pipe member to maximize the surface area to perform heat exchange with the refrigerant flowing in the pipe member by convection Member.

The heat transfer member is configured to maximize the heat transfer surface area by being coupled with the tube member to maximize the heat exchange with the refrigerant flowing through the tube member by the convection.

Meanwhile, the heat transfer heat exchanger 800 may further include an air flow forming unit (not shown) for forming an air flow toward the heat transfer member to enhance a heat exchange effect by convection.

By installing the electrothermal heat exchanger 800 as described above, it is possible to increase the cooling efficiency in the cooling section 560 by performing pre-cooling before entering the cooling section 560.

Particularly, the heat transfer heat exchanger 800 is installed in the vicinity of the second housing 200 having a relatively low temperature, so that the temperature difference of the second housing 200 can be utilized for cooling the refrigerant discharged from the heat transfer block 510.

The circulation pump 540 is connected to the refrigerant circulation pipe 530 through an inlet and an outlet of the circulation pump 540 so as to prevent the heated refrigerant passing through the heat transfer block 510 and passing through the circulation pump 540, And the coolant outlet 528 and the coolant inlet 529 of the heat transfer block 510 are connected to the coolant outlet port 528 and the coolant inlet port 529, respectively.

The cooling unit 560 is configured to cool the refrigerant heated through the heat transfer block 510 and installed between the circulation pump 540 and the heat transfer block 510 with respect to the flow direction of the refrigerant, Do.

The cooling unit 560 includes at least one main refrigerant tube connected to the refrigerant discharge port 528 of the heat transfer block 510 and the refrigerant circulation tube 530 and through which the refrigerant flows, And an auxiliary heat exchanger including a radiating fin for increasing the area.

Here, the radiating fin may be formed in various ways such as being integrally or detachably formed with the refrigerant pipe.

The cooling unit 560 may further include an auxiliary air flow forming unit installed in the first housing 100 to form an air flow toward the auxiliary heat exchanging unit to increase the cooling effect on the auxiliary heat exchanging unit .

The auxiliary air flow forming unit is configured to form an air flow to the first flow path P1 connecting the first air inlet 110 formed in the first housing 100 and the first air outlet 120, And the heat exchange can be performed in the auxiliary heat exchange unit by the air flow.

The auxiliary air flow forming portion forms an air flow of the first flow path (P1).

The cooling unit 560 is installed on the lower side of the heat transfer block 510 to facilitate the introduction of low temperature refrigerant.

The electrothermal heat exchanger (800) is installed to cool the refrigerant and may have various configurations.

For example, the heat transfer heat exchanger 800 may be installed between the heat transfer block 510 and the cooling unit 560 to cool the refrigerant flowing along the refrigerant circulation pipe 530.

The first housing 100 and the second housing 200 may have various structures and shapes according to the purpose of cooling or heating and may include a first heat exchanger and a second heat exchanger, Various configurations are possible.

Meanwhile, the first housing 100 and the second housing 200 may have various structures and shapes according to the purpose of cooling or heating, and may include a first Various configurations are possible if the configuration has a space.

The first housing 100 may have various constructions to form an inner space in which the first heat exchanging unit and the like are installed.

Also, although not specifically shown, the first housing 100 may be provided with one or more guide members to form the first flow path P1.

The first housing 100 may have a control panel for controlling the thermoelectric module unit, the second air flow forming unit, etc., an operation panel unit for controlling and operating the apparatus, a thermoelectric module unit, A power supply unit for supplying power to the air flow forming unit and the like, and a display unit installed on the front surface of the apparatus and indicating the state of the apparatus.

In this case, the electrical part of the power supply unit may be damaged by the condensation water due to the leakage of the condensed water or may be electrically charged by the user. In this case, the condensed water may be stored in the condensed water storage unit 250, It is preferable to set it higher.

The first housing 100 may have a shape having a pair of side surfaces connecting the upper surface and the lower surface, the upper surface and the lower surface opposed to each other with respect to the first heat exchanging portion, that is, a rectangular parallelepiped shape.

The second housing 200 is coupled to the first housing 100 to form a second air inlet 210 and a second air outlet 220. The second air inlet 210 and the second air outlet 220 And a second flow path P2 for connecting the first flow path P2 and the second flow path P2.

Meanwhile, the second housing 200 may be coupled with the first housing 100 in various forms.

For example, the second housing 200 may be installed inside the first housing 100, as shown in FIGS. 1 to 3 and 5 to 9.

The first housing 100 and the second housing 200 may be integrally formed with each other in addition to the embodiment shown in FIG. 1, or may have various configurations such as being opposed to each other with the thermoelectric module 300 as a center It is possible.

Meanwhile, the first housing 100 and the second housing 200 may be directly coupled by bolting or indirectly coupled by a thermoelectric module 300 to be described later.

The second air inlet 210 and the second air inlet 210 are provided in the second housing 200 so as to communicate with the first through hole 11 and the second through hole 12 formed in the structure 10 having a specific space to be cooled, An air outlet 220 is formed.

In this case, when the second housing 200 is installed inside the first housing 100, the first through hole 11 and the second through hole 12 formed in the structure 10 and the second through- A through hole 130 may be formed in the first housing 100 to allow the second air inlet 210 and the second air outlet 220 to communicate with each other.

At least one of the first housing 100 and the second housing 200 may further include a moving unit 600 to facilitate movement thereof.

The first housing 100 and the second housing 200 may be provided with one or more guide members (not shown) to form air passages P1 and P2 (not shown).

Meanwhile, during the heat exchange of the second heat exchanger, condensed water may be generated in the second heat exchanger, and the generated condensed water may flow downward to damage the electric parts.

Accordingly, in the present invention, a condensed water storage unit 250 for storing condensed water generated in the second heat exchanging unit during the heat exchange of the second heat exchanging unit is installed to solve the above problems.

The condensed water storage unit 250 is installed to store the condensed water generated in the second heat exchange unit and may have various structures.

As shown in FIGS. 1 and 2, the condensed water storage part 250 may be formed in a manner that a part of the wall of the second housing 200 can store condensed water.

The condensing water storage unit 250 may be integrally formed with the second housing 200 and the second housing 200 may be configured such that condensed water flows along the inner wall of the second housing 200 One or more inclined surfaces 202 may be formed so as to flow in the direction of the arrows 250.

In addition, a condensate removing unit 700 for removing condensed water stored in the condensed water storage unit 250 using ultrasonic waves may be further installed in the condensed water storage unit 250.

The condensed water removing unit 700 may be installed in the condensed water storing unit 250 so as to remove condensed water.

The condensed water vaporized by the condensed water removing unit 700 may be discharged in the indoor direction along the second flow path P2 forming the air flow by the second air flow forming unit 240.

At this time, the condensed water, which is vaporized by the condensed water removing unit 700 and discharged in the direction of the room, has an advantage that a humidifying effect can be given to the indoor space.

As shown in FIG. 3 and FIG. 5, the condensed water storage unit 250 may include an inlet 251 through which the condensed water flows and a discharge outlet formed by the condensed water removing unit 700, And a storage vessel 254 having an outlet 252.

The storage container 254 can have various constructions for storing condensed water.

The storage vessel 254 may be connected to the second housing 200 through a drain pipe 260 so that the condensed water storage unit 250 can be installed at a predetermined distance from the second housing 200.

The drain pipe 260 has a structure in which condensed water flowing on the inner wall on the lower side of the second heat exchanger can flow in the direction of the inlet 251 formed in the storage container 254.

For example, the drain pipe 260 may be a corrugated pipe having both ends connected to the inlet 251 of the condensed water storage unit 250 and the second housing 200, respectively.

On the other hand, if the condensed water collects in the storage container 254, it is necessary to periodically discharge the condensed water, which requires troublesome maintenance such as maintenance of the user.

Accordingly, the air conditioner according to the present invention may further include a condensate removing unit 700 for generating and removing the condensed water stored in the condensed water storage unit 250 by generating ultrasonic waves.

The condensed water removing unit 700 may be configured to generate condensed water stored in the condensed water storing unit 250 by generating ultrasonic waves.

For example, the condensed water removing unit 700 includes a vibrator (not shown) positioned at a proper position to form condensed water by spraying ultrasonic waves in the storage container 254 constituting the condensed water storage unit 250 .

The vibrator is provided in the storage container 254 to form a condensed water by spraying ultrasonic waves.

Meanwhile, the spray formed by the condensate remover 700 may be discharged to the outside or discharged to a specific space to be cooled, and utilized for controlling the humidity.

To this end, the condensate reservoir 250 may have one or more inlets 251 through which the condensed water flows and at least one outlet 252 through which the mist formed by the condensate removers 700 is discharged.

The inlet 251 is configured to allow the condensed water to flow through the second housing 200 and the drain pipe 260 so that the condensed water storage unit 250 can be installed at a position spaced apart from the second housing 200 Various configurations are possible.

At this time, the inlet 251 may be further provided with a filter for removing foreign substances, microorganisms, etc. from the introduced condensed water.

The discharge portion 252 may have various configurations as a configuration in which the spray formed by the condensed water removing portion 700 is discharged.

On the other hand, it is necessary to prevent the spray formed by the condensate remover 700 from re-entering into the specific space to be cooled through the discharge 252 as well as the inlet 251.

The condensate reservoir 250 is connected to the reservoir 254 so as to be immersed in the condensed water stored in the reservoir 254 to prevent the spray formed by the condensate remover 700 from flowing into the inlet 251. [ And a partition part 253 protruding downward from the ceiling of the main body part.

10, the condensed water storage part 250 is sprayed by the condensed water removing part 700 and the condensed water stored in the condensed water storage part 250 as the condensed water in the condensed water storage part 250 evaporates, The water level sensor 270 for measuring the water level in the condensed water storage unit 250 may be additionally provided.

The water level sensor 270 may be configured in various forms as a configuration for measuring the water level of the condensed water in the condensed water storage part 250 in which the spray is formed by the condensed water removing part 700.

The water level sensor 270 may be connected to a notification unit for notifying the user when the condensed water falls below a preset safe water level.

The notification unit is configured to inform the user when the condensed water of the water level sensor 270 falls below a predetermined safe water level, and may have various configurations.

The condensed water storage unit 250 may be provided in the condensed water storage unit 250 in accordance with necessity, for example, when the user arbitrarily fills the water or the condensed water falls below the safe water level for evaporation by the ultrasonic wave by the water level sensor 270, (Not shown).

The partition 253 is adapted to prevent the spray formed by the condensate removal unit 700 from flowing into the inlet 251 and from the ceiling of the storage vessel 254 to be submerged in the condensate stored in the storage vessel 254. [ Various members such as a partition wall may be used as the structure protruding downward.

Meanwhile, as described above, the second flow path P2 connecting the second air inlet 210 and the second air outlet 220 formed in the second housing 200 forming the specific space to be cooled is formed And a second air flow forming part (240) forming an air flow in the second flow path (P2) so that the heat exchange of the second heat exchange part is performed by the air flow of the second flow path (P2) The rejection 700 may include a first spray forming part that forms a spray to introduce the spray formed by the ultrasonic waves into the second flow path P2 through the inflow part 251. [

The first spray forming unit may include at least one ultrasonic vibrator that forms a spray to introduce the spray formed by the ultrasonic waves into the second flow path P2 through the inlet 251. [

As described above, when the first spray forming unit is installed to introduce the spray formed by the ultrasonic waves into the second flow path P2 through the inlet 251, the condensed water stored in the condensed water storage unit 250 is utilized for the humidifying function, It is possible to additionally provide a humidifying function for controlling the humidity in addition to the function of dehumidifying the specific space to be humidified.

At this time, the air conditioner according to the present invention may further include a humidity sensor (not shown) for measuring the humidity of the specific space described above in order to adjust the humidity.

The humidity sensor may have various configurations as a configuration for measuring the humidity of a specific space to be cooled for humidity control.

In the first and second embodiments, the first heat exchanging unit includes at least one heat transfer block 510 coupled to the heat dissipating unit of the thermoelectric module 300, and a heat exchange block 510 fixedly coupled to the heat transfer block 510. [ The heat exchange module includes a first flow path P1 connecting the first air inlet 120 formed in the first housing 100 in which the thermoelectric module 300 is installed and the first air outlet 110, When the heat exchange is performed by the first air flow forming unit 550 generating the flow, the condensed water removing unit 700 discharges the spray formed by the ultrasonic wave into the first flow path P1 through the discharge port 252, And a second spray forming part for forming a second spray forming part.

The second spray forming unit may include at least one ultrasonic vibrator that forms a spray to allow the spray formed by the ultrasonic waves to flow into the first flow path P1 through the discharge port 252. [

As described above, when the spray formed by the ultrasonic waves flows into the first flow path (P1) through the discharge port (252) by the second spray forming part, the condensed water stored in the condensed water storage part (250) .

Particularly, when the spray formed by ultrasonic waves to the first flow path P1 through the discharge port 252 is connected to the refrigerant flow path so as to pass through the cooling part 560 through which the refrigerant flows, the humidity in the cooling part 560 increases, It is possible to maximize the cooling effect on the heat exchanger 560.

Further, the condensed water flows toward the cooling part 560 in a sprayed state, and water is not splashed to the periphery, thereby preventing damage or malfunction of the electric parts.

Meanwhile, the first spray forming part and the second spray forming part may be installed at the same time, and at the same time, the condensing water stored in the condensed water storage part 250 may be removed, or may be utilized as a humidifying function.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

250: condensed water storage part 300: thermoelectric module
700: Ultrasonic generator 800: Total heat exchanger

Claims (7)

One or more thermoelectric modules (300) formed with a heat dissipation unit and a heat absorption unit;
A first heat exchanging part and a second heat exchanging part coupled to the heat radiating part and the heat absorbing part of the thermoelectric module 300;
And a condensed water storage part (250) for storing condensed water generated during heat exchange in the second heat exchange part. The method according to claim 1,
Further comprising a condensate removing unit (700) for removing condensed water stored in the condensed water storage unit (250) by using an ultrasonic wave. The method according to claim 1,
The condensed water storage part 250 may include:
And a storage vessel (254) having an inlet (251) through which condensate flows and at least one outlet (252) through which the spray formed by the condensate removal (700) is discharged. The method of claim 3,
The condensed water storage part 250 may include:
Is protruded downward from the ceiling of the storage vessel 254 so as to be submerged in the condensed water stored in the storage vessel 254 in order to prevent the spray formed by the condensed water removing unit 700 from flowing into the inlet 251 And a partitioning part (253) formed on the partition wall (25). The method of claim 4,
A second flow path P2 connecting the second air inlet 210 and the second air outlet 220 formed in the housing 200 forming the specific space to be cooled is formed,
And a second air flow forming part (240) forming an air flow in the second flow path (P2) so that the heat exchange of the second heat exchange part is performed by the air flow of the second flow path (P2)
The condensate removing unit 700 includes:
And a first spray-forming part for spraying the spray formed by ultrasonic waves into the second flow path (P2) through the inflow part (251). The method of claim 4,
Wherein the first heat exchanger comprises:
At least one heat transfer block 510 coupled to the heat dissipation unit of the thermoelectric module 300 and a heat exchange module fixedly coupled to the heat transfer block 510,
The heat exchange module includes a first air path P1 connecting a first air inlet 120 formed in a housing in which the thermoelectric module 300 is installed and a first air outlet 110, Heat exchange is performed by the flow forming part 550,
The condensate removing unit 700 includes:
And a second spray forming part for spraying the spray formed by ultrasonic waves into the first flow path (P1) through the discharge port (252). The method of claim 4,
A second flow path P2 connecting the second air inlet 210 and the second air outlet 220 formed in the housing 200 forming the specific space to be cooled is formed,
And a second air flow forming part (240) forming an air flow in the second flow path (P2) so that the heat exchange of the second heat exchange part is performed by the air flow of the second flow path (P2)
Wherein the first heat exchanger comprises:
At least one heat transfer block 510 coupled to the heat dissipation unit of the thermoelectric module 300 and a heat exchange module fixedly coupled to the heat transfer block 510,
The heat exchange module includes a first air path P1 connecting a first air inlet 120 formed in a housing in which the thermoelectric module 300 is installed and a first air outlet 110, Heat exchange is performed by the flow forming part 550,
The condensate removing unit 700 includes:
A first spray forming part for spraying the spray formed by the ultrasonic waves into the second flow path (P2) through the inflow part (251)
And a second spray forming part for spraying the spray formed by ultrasonic waves into the first flow path (P1) through the discharge port (252).

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