LAUNDRY TREATMENT APPARATUS

Abstract

A laundry treatment apparatus includes a laundry receiving unit, a duct for supplying air to the laundry receiving unit, a first heat exchanger for exchanging heat with air introduced into the duct, a second heat exchanger located in the duct for exchanging heat with air that has passed through the first heat exchanger, and a heat transfer unit. The heat transfer unit includes a first conductor making contact with the first heat exchanger and connected to a positive electrode of a direct current (DC) power source, a second conductor making contact with the first heat exchanger and connected to a negative electrode of the DC power source, the second conductor being separated from the first conductor, a third conductor making contact with the second heat exchanger, a P-type semiconductor interconnecting the first conductor and the third conductor, and an N-type semiconductor interconnecting the second conductor and the third conductor.

Description

Pursuant to 35 U.S.C. §119(a), this application claims the benefit of Korean Patent Application No. 10-2014-0026455, filed on Mar. 6, 2014, which is hereby incorporated by reference as if fully set forth herein.

TECHNICAL FIELD

The present application relates to a laundry treatment apparatus.

BACKGROUND

A laundry treatment apparatus is a generic term for apparatuses having a washing function and/or a drying function of laundry (an object to be washed). Examples of the laundry treatment apparatus include a washing machine, a drying machine, and a combined washing and drying machine.

Laundry treatment apparatuses capable of drying laundry may be classified into those having an exhaust drying system and those having a circulation (condensation) drying system according to the flow of heated air (hot air) to be supplied to laundry.

A circulation drying system is configured to remove moisture from air discharged from a laundry receiving unit (i.e. to dehumidify the air), to heat the dehumidified air, and to resupply the dehumidified and heated air to the laundry receiving unit. An exhaust drying system is configured to supply heated air to a laundry receiving unit and to outwardly discharge the air discharged from the laundry receiving unit rather than resupplying the air to the laundry receiving unit.

Most conventional circulation drying systems require a dehumidifier to cool air discharged from the laundry receiving unit so as to remove moisture from the air as well as a heater to heat the dehumidified air.

SUMMARY

According to one aspect, a laundry treatment apparatus includes a laundry receiving unit configured to provide a space for receiving laundry, a duct configured to supply air to the laundry receiving unit, a first heat exchanger configured to exchange heat with air introduced into the duct, a second heat exchanger located in the duct and configured to exchange heat with air that has passed through the first heat exchanger, and a heat transfer unit. The heat transfer unit includes a first conductor that makes contact with the first heat exchanger and is connected to a positive electrode of a direct current (DC) power source, a second conductor that makes contact with the first heat exchanger and is connected to a negative electrode of the DC power source, the second conductor being separated from the first conductor, a third conductor that makes contact with the second heat exchanger, a P-type semiconductor configured to interconnect the first conductor and the third conductor, and an N-type semiconductor configured to interconnect the second conductor and the third conductor.

Implementations according to this aspect may include one or more of the following features. For example, the duct may include an exhaust duct configured to discharge air coming from an interior of the laundry receiving unit to an outside of the laundry receiving unit and a supply duct configured to guide air from the outside of the laundry receiving unit to the laundry receiving unit, and the first heat exchanger, the second heat exchanger, and the heat transfer unit may be located inside the supply duct. The laundry receiving unit may include a tub placed inside a cabinet, an inlet port and an outlet port in communication with the outside of the laundry receiving unit, and a drum placed inside the tub and configured to provide the space for receiving laundry, and the duct may be configured to connect the outlet port and the inlet port to each other. The first heat exchanger may include a heat absorption body located inside the duct, the first conductor and the second conductor being secured to the heat absorption body, and heat absorption fins protruding from the heat absorption body, and the second heat exchanger may include a heat radiation body spaced apart from the first heat exchanger in a longitudinal direction of the duct, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body. The heat absorption fins and the heat radiation fins may be arranged parallel to a movement direction of air within the duct that is moving toward the inlet port. The heat absorption fins may include a plurality of conductive plates spaced apart from one another by a prescribed distance, and the heat radiation fins may include a plurality of conductive plates spaced apart from one another by a prescribed distance, one heat radiation fin being located in a space between one heat absorption fin and another heat absorption fin and arranged parallel to the heat absorption fins. The heat absorption fins may protrude from the heat absorption body toward a lower surface of a cross section of the duct, and the heat radiation fins may protrude from the heat radiation body toward the lower surface of the cross section of the duct. The first heat exchanger may include a heat absorption body located inside the duct, heat absorption fins protruding from the heat absorption body to a lower surface of a cross section of the duct, and an extension body extending from the heat absorption body in a longitudinal direction of the duct, the first conductor and the second conductor being secured to the extension body, and the second heat exchanger may include a heat radiation body located below the extension body, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body toward the lower surface of the cross section of the duct. The laundry treatment apparatus according to this aspect may further include a heater located inside the duct and configured to heat air that has passed through the second heat exchanger.

According to another aspect, a laundry treatment apparatus includes a laundry receiving unit configured to provide a space for receiving laundry, a duct configured to supply air to the laundry receiving unit, a first heat exchanger configured to exchange heat with air introduced into the duct, a second heat exchanger configured to exchange heat with air that has passed through the first heat exchanger, a heater located inside the duct configured to heat air that has passed through the second heat exchanger, and a heat transfer unit. The heat transfer unit includes a first conductor that makes contact with the first heat exchanger and is connected to a positive electrode of a DC power source, a second conductor that makes contact with the first heat exchanger and is connected to a negative electrode of the DC power source, the second conductor being separated from the first conductor, a third conductor that makes contact with the second heat exchanger, a P-type semiconductor configured to interconnect the first conductor and the third conductor, and an N-type semiconductor configured to interconnect the second conductor and the third conductor.

Implementations according to this aspect may include one or more of the following features. For example, the duct may include an exhaust duct configured to discharge air coming from an interior of the laundry receiving unit to an outside of the laundry receiving unit and a supply duct configured to guide air from the outside of the laundry receiving unit to the laundry receiving unit, and the first heat exchanger, the second heat exchanger, and the heat transfer unit may be located inside the supply duct. The laundry receiving unit may include a tub placed inside a cabinet, an inlet port and an outlet port in communication with the outside of the laundry receiving unit, and a drum placed inside the tub and configured to provide the space for receiving laundry, and the duct may be configured to connect the outlet port and the inlet port to each other. The first heat exchanger may include a heat absorption body located inside the duct, the first conductor and the second conductor being secured to the heat absorption body, and heat absorption fins protruding from the heat absorption body, and the second heat exchanger may include a heat radiation body spaced apart from the first heat exchanger in a longitudinal direction of the duct, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body. The heat absorption fins and the heat radiation fins may be arranged parallel to a movement direction of air within the duct that is moving toward the inlet port. The heat absorption fins may include a plurality of conductive plates spaced apart from one another by a prescribed distance, and the heat radiation fins may include a plurality of conductive plates spaced apart from one another by a prescribed distance, one heat radiation fin being located in a space between one heat absorption fin and another heat absorption fin and arranged parallel to the heat absorption fins. The heat absorption fins may protrude from the heat absorption body toward a lower surface of a cross section of the duct, and the heat radiation fins may protrude from the heat radiation body toward the lower surface of the cross section of the duct. The first heat exchanger may include a heat absorption body located inside the duct, heat absorption fins protruding from the heat absorption body to a lower surface of a cross section of the duct, and an extension body extending from the heat absorption body in a longitudinal direction of the duct, the first conductor and the second conductor being secured to the extension body, and the second heat exchanger may include a heat radiation body located below the extension body, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body toward the lower surface of the cross section of the duct.

It is to be understood that both the foregoing general description and the following detailed description of the present application are exemplary and explanatory and are intended to provide further explanation of the present application as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary laundry treatment apparatus according to the present application;

FIGS. 2A and 2B illustrate an exemplary heat exchange module included in the laundry treatment apparatus according to the present application; and

FIGS. 3A and 3B illustrates another implementation of the heat exchange module included in the laundry treatment apparatus according to the present application.

DETAILED DESCRIPTION

Hereinafter, exemplary implementations of the present application will be described in detail with reference to the accompanying drawings. A configuration or control method of an apparatus that will be described below is intended to illustrate the implementations of the present application and not intended to limit the scope of the present application.

A laundry treatment apparatus 100 of the present application includes a cabinet 1 defining the external appearance of the apparatus 100, a laundry receiving unit placed inside the cabinet 1 to provide a space in which laundry (i.e. washing object or drying object) is received, and an air supply unit 6 to supply air to the laundry receiving unit so as to dry the laundry.

The cabinet 1 has an opening 11 for introduction/removal of laundry and a door 13 is coupled to the cabinet 1 to open or close the opening 11.

In a case in which the laundry treatment apparatus 100 of the present application is designed to implement both washing and drying of laundry, the laundry receiving unit can include a tub 2 placed inside the cabinet 1 to provide a water storage space and a drum 3 placed inside the tub 2 to provide a laundry receiving space. In this case, the air supply unit 6 is configured to supply air to the tub 2.

The tub 2 may take the form of a cylinder having a tub opening 21 corresponding to the opening 11. The tub 2 may be fixed inside the cabinet 1 via a tub support member 15.

A gasket 23 is interposed between the tub opening 21 and the opening 11 to prevent leakage of water stored in the tub 2 and to prevent transmission of vibration from the tub 2 to the cabinet 1.

The drum 3 may take the form of a cylinder having a drum opening 31 in communication with the tub opening 21. The drum is provided at the outer periphery thereof including the circumference thereof with through-holes 33 to communicate the inside of the drum 3 with the inside of the tub 2.

In a case in which the drum 3 is rotatably installed inside the tub 2, a rotating shaft 35 may be installed to a rear surface of the drum 3 (opposite to a drum surface provided with the drum opening 31) so as to penetrate a rear surface of the tub 2.

A drive unit 4 may be installed to a rear surface of the tub 2 to rotate the rotating shaft 35. The drive unit 4 may include a stator 41 secured to the rear surface of the tub 2, the stator 41 creating a rotation magnetic field upon receiving current from an external power source, and a rotor 43 configured to be rotated by the rotation magnetic field created by the stator 41, the rotating shaft 35 being coupled to the rotor 43.

Water required for washing of laundry may be supplied to the tub 2 through a water supply unit configured to interconnect the tub 2 and a water source. The water stored in the tub 2 may be outwardly discharged from the cabinet 1 through a drain unit 5.

In cases in which the laundry treatment apparatus 100 of the present application includes a circulation drying system, the tub 2 may further include an outlet port 25 and an inlet port 27 to communicate the inside of the tub 2 with the outside of the tub 2. In this case, the air supply unit 6 is configured to dehumidify and heat air discharged from the outlet port 25 and to resupply the air to the tub 2 through the inlet port 27.

To this end, the air supply unit 6 can include a duct 61 connecting the outlet port 25 and the inlet port 27 to each other, a fan 63 located inside the duct 61 to circulate interior air of the tub 2, and a heat exchange module F located inside the duct 61 between the fan 63 and the inlet port 27 to sequentially implement dehumidification and heating of air moving in the duct 61.

In some cases, when the laundry treatment apparatus 100 of the present application includes an exhaust drying system, the above-described duct 61 may be divided into an exhaust duct that is connected to the outlet port 25 and a supply duct that is connected to the inlet port 27. Such exhaust duct may be configured to communicate the inside of the tub 2 with the outside of the cabinet 1 and the supply duct may be configured to communicate the inside of the tub 2 with the inside of the cabinet 1 or the outside of the cabinet 1. In this case, the fan 63 may be located inside the exhaust duct and the heat exchange module F may be located inside the supply duct.

Referring also to FIG. 2A, regardless of whether the laundry treatment apparatus 100 of the present application includes a circulation drying system or an exhaust drying system, the heat exchange module F may include a first heat exchanger 67 to exchange heat with air supplied through the fan 63, a second heat exchanger 65 to exchange heat with air having passed through the first heat exchanger 67, and a heat transfer unit 69 located between the first heat exchanger 67 and the second heat exchanger 65.

As exemplarily illustrated in FIG. 2A, the heat transfer unit 69 according to the present application may include a first conductor 691 coming into contact with the first heat exchanger 67, a second conductor 693 coming into contact with the first heat exchanger 67 and spaced apart from the first conductor 691 by a prescribed distance, a third conductor 695 coming into contact with the second heat exchanger 65, a P-type semiconductor 697 to interconnect the first conductor 691 and the third conductor 695, and an N-type semiconductor 699 to interconnect the second conductor 693 and the third conductor 695.

The P-type semiconductor 697 refers to a material in which the number of holes having positive charge (+charge) is greater than the number of free electrons, and the N-type semiconductor 699 refers to a material in which the number of holes is less than the number of free electrons.

As shown in FIG. 2A, the first conductor 691 is connected to a positive electrode of a direct current (DC) power source S and the second conductor 693 is connected to a negative electrode of the DC power source S.

In the heat exchange module F having the above-described configuration, when the DC power source S supplies direct current to the first conductor 691 and the second conductor 693, the first conductor 691 and the second conductor 693 are cooled and the third conductor 695 is heated.

In this way, when the first heat exchanger 67 and the second heat exchanger 65 are formed of conductive materials, the first heat exchanger 67 secured to the first conductor 691 and the second conductor 693 functions as a heat absorber to absorb external heat, and the second heat exchanger 65 secured to the third conductor 695 functions as a heat radiator to outwardly radiate heat.

To allow the first heat exchanger 67 and the second heat exchanger 65 as described above to respectively implement dehumidification and heating of air introduced into the duct 61, the first heat exchanger 67 and the second heat exchanger 65 may be sequentially arranged in a direction from the fan 63 to the inlet port 27.

That is, air introduced into the duct 61 through the outlet 25 may be directed to the first heat exchanger 67 by way of the fan 63 and the air having passed through the first heat exchanger 67 may sequentially pass through the second heat exchanger 65 and the inlet port 27 so as to be resupplied to the tub 2.

To this end, the first heat exchanger 67 may include a heat absorption body 671 located inside the duct 61, the first conductor 691 and the second conductor 693 being secured to the heat absorption body 671, and heat absorption fins 673 protruding from the heat absorption body 671.

In some cases, the second heat exchanger 65 may include a heat radiation body 651 located between the heat absorption body 671 and the inlet port 27, the third conductor 695 being secured to the heat radiation body 651, and heat radiation fins 653 protruding from the heat radiation body 651.

The heat absorption body 671, heat absorption fins 673, heat radiation body 651, and heat radiation fins 653 may be formed of conductive materials and the heat absorption fins 673 and the heat radiation fins 653 may be arranged parallel to a movement direction X of air directed to the inlet port 27 as exemplarily illustrated in FIG. 2B.

That is, the heat absorption fins 673 may be a plurality of plates (conductive plates) arranged at a lower surface of the heat absorption body 671 to extend in the longitudinal direction L of the duct 61 and spaced apart from one another by a prescribed distance in the width direction W of the duct 61. The heat radiation fins 653 may be a plurality of plates (conductive plates) arranged at a lower surface of the heat radiation body 651 to extend in the longitudinal direction L of the duct 61 and spaced apart from one another by a prescribed distance in the width direction W of the duct 61. This arrangement can serve to minimize reduction in the flow rate of air when the air passes through the heat exchange module F.

While the heat absorption fins 673 and the heat radiation fins 653 may be positioned on the same lines as exemplarily illustrated in FIG. 2B, each of the heat radiation fins 653 may be located in a space 674 between one heat absorption fin 673a and another heat absorption fin 673b, in order to enhance heat exchange efficiency.

In some cases, the first heat exchanger 67 may further include heat absorption fins protruding from the heat absorption body 671 to extend in the width direction W of the duct 61 and the second heat exchanger 65 may further include heat radiation fins protruding from the heat radiation body 651 to extend in the width direction W of the duct 61.

However, in consideration of the fact that moisture contained in air may be condensed at a surface of the first heat exchanger 67 while passing through the first heat exchanger 67, the heat absorption fins 673 may protrude from the heat absorption body 671 only to a lower surface B of the duct 61 (i.e. a lower surface on the basis of the cross section of the duct 61). In this case, the heat radiation fins 653 may include fins protruding from the heat radiation body 651 to the lower surface B of the duct 61 and fins protruding from the heat radiation body 651 to extend in the width direction W of the duct 61.

In the laundry treatment apparatus 100 having the above-described configuration, air introduced into the duct 61 by the fan 63 can be dehumidified while passing through the first heat exchanger 67 and heated while passing through the second heat exchanger 65, thereafter being directed to laundry inside the drum 3 through the inlet port 27 and the through-holes 33.

To discharge water that has condensed due to air coming from the duct 61 and passing through the first heat exchanger 67, according to the present application, the heat exchange module F may further include a sump located below the first heat exchanger 67 to store the condensed water and a discharge pipe to communicate the sump with the outside of the cabinet 1.

FIGS. 3A and 3B illustrate a heat exchange module F′, which is another implementation of the heat exchange module F included in the laundry treatment apparatus 100 according to the present application.

While the heat exchange module F′ according to the present implementation includes a first heat exchanger 67′, a second heat exchanger 65′, and a heat transfer unit 69′ in a similar manner as that of the implementation of FIGS. 2A and 2B, positions of the first heat exchanger 67′ and the second heat exchanger 65′ differ from those in the implementation of FIGS. 2A and 2B.

The second heat exchanger 65′ according to this implementation may include a heat radiation body 651′ secured to a third conductor 695′ and heat radiation fins 653′ protruding from a heat radiation body 651′ to the lower surface B of the duct 61.

In more detail, the first heat exchanger 67′ according to the present implementation includes a heat absorption body 671′ located between a heat radiation body 651′ and the fan 63, heat absorption fins 673′ protruding from the heat absorption body 671′ to the lower surface B of the duct 61, and an extension body 672′ extending from the heat absorption body 671′ in the longitudinal direction L of the duct 61 so as to be located above the heat radiation body 651′, a first conductor 691′ and a second conductor 693′ being secured to an extension body 672′.

In the heat transfer unit 69′ including a P-type semiconductor 697′ and a N-type semiconductor 699′, a theoretical amount of heat absorption is 160 assuming that the amount of heat absorption through the first heat exchanger 67′ is 60 and the amount of electric power supplied from the DC power source S is 100′.

Accordingly, since heat radiation through the second heat exchanger 65′ may increase when heat absorption through the first heat exchanger 67′ increases under application of a constant amount of electric power to the heat transfer unit 69′, the extension body 672′ of the first heat exchanger 67′ serves to increase the amount of heat absorption through the first heat exchanger 67′ and, consequently, increase heat radiation through the second heat exchanger 65′.

Characteristics of the heat absorption fins 673′ and the heat radiation fins 653′ and characteristics of the heat transfer unit 69′ are similar to those of their counterparts as in the above-described implementation of FIGS. 2A and 2B and a detailed description thereof will be omitted herein.

The above-described implementations may further include a heater 7 (see FIG. 1) located between the inlet port 27 and the heat exchange module F′ to heat air having passed through the second heat exchanger 65′ for the sake of rapid laundry drying.

The heater 7 may be configured to heat air using Joule heating generated when current is supplied to, for example, a resistive wire.

While the above-described implementations have been described based on a case in which the laundry treatment apparatus 100 is capable of washing and drying laundry, the above-described characteristics may be applied to a laundry treatment apparatus that performs only drying of laundry.

In the case of the laundry treatment apparatus that performs only drying of laundry, it is noted that a laundry receiving unit includes only the drum 3 placed inside the cabinet 1 and the air supply unit 6 is configured to supply air to the drum 3.

In addition, when the drum 3 needs to be rotatable inside the cabinet 1, the cabinet 1 may additionally need to internally incorporate a front support portion to rotatably support the drum opening 31 and a rear support portion spaced apart from the rear surface of the drum 3 by a prescribed distance to rotatably support the rotating shaft 35.

In such case, the front support portion may be provided with a support portion opening in communication with the opening 11 of the cabinet 1, and the inlet port 27 and the outlet port 25 may be respectively formed in the front support portion and the rear support portion.

As is apparent from the above description, the present application can have the effect of providing a laundry treatment apparatus having high drying efficiency.

In addition, the present application can have the effect of providing a laundry treatment apparatus in which a device to remove moisture from air and a device to heat the air are integrated.

Although the exemplary implementations have been illustrated and described as above, of course, it will be apparent to those skilled in the art that the implementations are provided to assist understanding of the present application and the present application is not limited to the above described particular implementations, and various modifications and variations can be made in the present application without departing from the spirit or scope of the present application, and the modifications and variations should not be understood individually from the viewpoint or scope of the present application.

Claims

1. A laundry treatment apparatus comprising:

a laundry receiving unit configured to provide a space for receiving laundry;

a duct configured to supply air to the laundry receiving unit;

a first heat exchanger configured to exchange heat with air introduced into the duct;

a second heat exchanger located in the duct and configured to exchange heat with air that has passed through the first heat exchanger; and

a heat transfer unit including: a first conductor that makes contact with the first heat exchanger and is connected to a positive electrode of a direct current (DC) power source, a second conductor that makes contact with the first heat exchanger and is connected to a negative electrode of the DC power source, the second conductor being separated from the first conductor, a third conductor that makes contact with the second heat exchanger, a P-type semiconductor configured to interconnect the first conductor and the third conductor, and an N-type semiconductor configured to interconnect the second conductor and the third conductor.

2. The laundry treatment apparatus according to claim 1, wherein:

the duct includes an exhaust duct configured to discharge air coming from an interior of the laundry receiving unit to an outside of the laundry receiving unit and a supply duct configured to guide air from the outside of the laundry receiving unit to the laundry receiving unit; and

the first heat exchanger, the second heat exchanger, and the heat transfer unit are located inside the supply duct.

3. The laundry treatment apparatus according to claim 1, wherein:

the laundry receiving unit includes a tub placed inside a cabinet, an inlet port and an outlet port in communication with the outside of the laundry receiving unit, and a drum placed inside the tub and configured to provide the space for receiving laundry; and

the duct is configured to connect the outlet port and the inlet port to each other.

4. The laundry treatment apparatus according to claim 3, wherein:

the first heat exchanger includes a heat absorption body located inside the duct, the first conductor and the second conductor being secured to the heat absorption body, and heat absorption fins protruding from the heat absorption body; and

the second heat exchanger includes a heat radiation body spaced apart from the first heat exchanger in a longitudinal direction of the duct, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body.

5. The laundry treatment apparatus according to claim 4, wherein the heat absorption fins and the heat radiation fins are arranged parallel to a movement direction of air within the duct that is moving toward the inlet port.

6. The laundry treatment apparatus according to claim 5, wherein:

the heat absorption fins include a plurality of conductive plates spaced apart from one another by a prescribed distance; and

the heat radiation fins include a plurality of conductive plates spaced apart from one another by a prescribed distance, one heat radiation fin being located in a space between one heat absorption fin and another heat absorption fin and arranged parallel to the heat absorption fins.

7. The laundry treatment apparatus according to claim 5, wherein:

the heat absorption fins protrude from the heat absorption body toward a lower surface of a cross section of the duct; and

the heat radiation fins protrude from the heat radiation body toward the lower surface of the cross section of the duct.

8. The laundry treatment apparatus according to claim 3, wherein:

the first heat exchanger includes a heat absorption body located inside the duct, heat absorption fins protruding from the heat absorption body to a lower surface of a cross section of the duct, and an extension body extending from the heat absorption body in a longitudinal direction of the duct, the first conductor and the second conductor being secured to the extension body; and

the second heat exchanger includes a heat radiation body located below the extension body, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body toward the lower surface of the cross section of the duct.

9. The laundry treatment apparatus according to any one of claim 1, further comprising a heater located inside the duct and configured to heat air that has passed through the second heat exchanger.

10. A laundry treatment apparatus comprising:

a laundry receiving unit configured to provide a space for receiving laundry;

a duct configured to supply air to the laundry receiving unit;

a first heat exchanger configured to exchange heat with air introduced into the duct;

a second heat exchanger configured to exchange heat with air that has passed through the first heat exchanger;

a heater located inside the duct configured to heat air that has passed through the second heat exchanger; and

a heat transfer unit including: a first conductor that makes contact with the first heat exchanger and is connected to a positive electrode of a direct current (DC) power source, a second conductor that makes contact with the first heat exchanger and is connected to a negative electrode of the DC power source, the second conductor being separated from the first conductor, a third conductor that makes contact with the second heat exchanger, a P-type semiconductor configured to interconnect the first conductor and the third conductor, and an N-type semiconductor configured to interconnect the second conductor and the third conductor.

11. The laundry treatment apparatus according to claim 10, wherein:

the duct includes an exhaust duct configured to discharge air coming from an interior of the laundry receiving unit to an outside of the laundry receiving unit and a supply duct configured to guide air from the outside of the laundry receiving unit to the laundry receiving unit; and

the first heat exchanger, the second heat exchanger, and the heat transfer unit are located inside the supply duct.

12. The laundry treatment apparatus according to claim 10, wherein:

the laundry receiving unit includes a tub placed inside a cabinet, an inlet port and an outlet port in communication with the outside of the laundry receiving unit, and a drum placed inside the tub and configured to provide the space for receiving laundry; and

the duct is configured to connect the outlet port and the inlet port to each other.

13. The laundry treatment apparatus according to claim 12, wherein:

the first heat exchanger includes a heat absorption body located inside the duct, the first conductor and the second conductor being secured to the heat absorption body, and heat absorption fins protruding from the heat absorption body; and

the second heat exchanger includes a heat radiation body spaced apart from the first heat exchanger in a longitudinal direction of the duct, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body.

14. The laundry treatment apparatus according to claim 13, wherein the heat absorption fins and the heat radiation fins are arranged parallel to a movement direction of air within the duct that is moving toward the inlet port.

15. The laundry treatment apparatus according to claim 14, wherein:

the heat absorption fins include a plurality of conductive plates spaced apart from one another by a prescribed distance; and

the heat radiation fins include a plurality of conductive plates spaced apart from one another by a prescribed distance, one heat radiation fin being located in a space between one heat absorption fin and another heat absorption fin and arranged parallel to the heat absorption fins.

16. The laundry treatment apparatus according to claim 14, wherein:

the heat absorption fins protrude from the heat absorption body toward a lower surface of a cross section of the duct; and

the heat radiation fins protrude from the heat radiation body toward the lower surface of the cross section of the duct.

17. The laundry treatment apparatus according to claim 12, wherein:

the first heat exchanger includes a heat absorption body located inside the duct, heat absorption fins protruding from the heat absorption body to a lower surface of a cross section of the duct, and an extension body extending from the heat absorption body in a longitudinal direction of the duct, the first conductor and the second conductor being secured to the extension body; and

the second heat exchanger includes a heat radiation body located below the extension body, the third conductor being secured to the heat radiation body, and heat radiation fins protruding from the heat radiation body toward the lower surface of the cross section of the duct.