KR20150124353A - Clothes dryer - Google Patents

Abstract

The present invention relates to a clothing drier. The clothing drier includes: a cabinet; a drum which is arranged in the cabinet to provide a space for storing laundry; an air suction duct forming a flow path to supply hot air into the drum; a heating unit which heat the air flowing into the air suction duct; and an air discharging duct which forms another flow path to discharge the air from the drum. An air discharging flow path which discharges the air discharged from the drum to the outside of the cabinet through the air discharging duct is arranged on the cabinet as well as an air suction flow path guiding the air in the cabinet or the outside air into the drum. A heat exchanger is arranged on the air discharging flow path in order to enable the heat exchange between the air being discharged to the air discharging path and the air flowing into the air suction path therein.

Description

Clothes dryer

The present invention relates to a clothes dryer capable of reducing heat loss.

Generally, a clothes dryer refers to a clothes dryer in which a laundry having been completely washed is put into a drum (or a tub) of a dryer, and hot air is supplied to the drum to evaporate moisture from the laundry to dry the laundry Device.

The dryer includes a drum, a driving motor for driving the drum, a blowing fan for blowing air into the drum, and a heating means for heating the air flowing into the drum.

The air in the clothes dryer evaporates the moisture of the laundry, and the air escapes from the drum, and the moisture of the laundry in the drum is retained, resulting in a high-temperature and high-humidity air.

Dryers can be classified according to the method of treating hot and humid air.

The exhaust type dryer is a dryer configured to supply outside air to the drum and to dry the object to be dried in the drum, and then to discharge the hot and humid air to the outside.

The condensing dryer is a dryer configured to dehumidify hot and humid air, which is dried in a drum, through a condenser, and then supply the heated air to the inside of the drum again.

In any type of dryer, the heated air heated by the heating means is fed into the drum through the intake duct. At this time, as the heating means, a combustion heater using fuel such as liquefied gas or an electric heating heater using electric resistance is used.

At this time, only a part of the heat generated by the heater is used to generate hot air, and the remaining heat is not used in the drying process of the laundry and is discharged to the outside of the intake duct, thereby causing heat loss.

On the other hand, in the condensing dryer, hot air, which has been in a state of high temperature and high humidity, exchanges heat with the laundry in the drum, circulates without being discharged to the outside of the dryer, and reuses the heat energy.

On the other hand, in the exhaust type dryer, the hot and humid hot air discharged from the drum is directly discharged to the outside of the cabinet through the exhaust duct, so that the heat energy of the exhausted air can not be reused.

Accordingly, there is a demand for a heat recovery system capable of recovering heat energy of hot air discharged from a drum in an exhaust-type dryer to increase energy efficiency.

Further, in the exhaust type dryer, since the air intake hole is provided in the rear of the cabinet, the air flow path to the intake duct becomes complicated, and the air intake rate is lowered, and the air resistance is increased, and the motor is overloaded.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a clothes dryer capable of minimizing the flow resistance of air flowing in to generate hot air.

An object of the present invention is to provide a clothes dryer capable of smoothly supplying air for hot wind generation and reducing motor load for air inflow.

The present invention provides a clothes dryer capable of reducing energy for generating hot air by recovering heat energy discharged by preheating air introduced from the outside of a cabinet using hot air discharged from a drum and guiding the air to an intake duct The purpose.

An object of the present invention is to provide a clothes dryer capable of minimizing the loss of heat energy by preheating air flowing into an intake duct by using heat of loss generated in a heater during a process of generating hot air for washing laundry.

An object of the present invention is to provide a clothes dryer capable of preventing an accident caused by high temperature air discharged by lowering the temperature of air discharged through an exhaust duct.

Another object of the present invention is to provide a clothes dryer having high energy efficiency.

In order to accomplish the above object, the present invention provides the following solutions.

According to one aspect of the present invention, there is provided a clothes dryer including a cabinet, a drum provided in the cabinet for providing a space for accommodating laundry, an intake duct for supplying hot air to the drum, A heating unit for heating the air introduced into the intake duct, and an exhaust duct for exhausting air from the drum.

In addition, a divided space in which the first direction flow of the air introduced from the inside or the outside of the cabinet and the second direction flow of the air discharged from the drum respectively are provided in the exhaust duct, And a heat exchanger in which heat exchange occurs between the first directional flow and the second directional flow.

The clothes dryer according to one aspect of the present invention is characterized in that the first directional flow and the second directional flow which flow through the heat exchanger intersect at a predetermined angle.

The air conditioner may further include a preheating member for guiding the air passing through the heat exchanger to the intake duct and forming a heat exchange space through which heat is exchanged between the air passing through the heat exchanger and the air flowing into the intake duct from the intake duct. have.

An air inlet is provided at the lower surface of the exhaust duct opposite to the bottom of the cabinet. Air is introduced into the lower surface of the cabinet. The upper surface of the exhaust duct is spaced apart from the lower surface of the exhaust duct by a predetermined distance An air outlet through which one air is discharged can be provided.

The first directional flow introduced into the air inlet may be discharged to the air discharge port, and then may flow to the intake duct.

The first directional flow passes through the heat exchanger and is subjected to first heat exchange with the second directional flow, and then is heat-exchanged with heat radiated from the intake duct while flowing to the intake duct, thereby being preheated, thereby reusing heat energy lost in the clothes dryer Thereby minimizing thermal energy loss.

According to another aspect of the present invention, there is provided a clothes dryer including a cabinet, a drum provided inside the cabinet for providing a space for accommodating laundry, an air intake duct for forming a path for supplying hot air to the drum, A heating unit for heating, and an exhaust duct for forming a flow path for discharging air from the drum.

In the cabinet, an exhaust passage through which air discharged from the drum is discharged to the outside of the cabinet through the exhaust duct, and an intake passage through which air in the cabinet or outside is guided to the drum may be formed.

A heat exchanger is provided on the exhaust flow path, and heat exchange occurs between air discharged from the heat exchanger to the exhaust flow path and air introduced into the intake flow path.

In particular, the clothes dryer of the present invention guides the air that has passed through the heat exchanger to the intake duct to recover the discarded heat and preheat the air to be dried, And a heat-exchanging space for heat-exchanging heat with heat radiated from the intake duct.

The preheating member is provided on the upper side of the exhaust duct and may be formed integrally with the exhaust duct. That is, the preheating member may be fixed to the upper side of the exhaust duct.

The preheating member preheats the air flowing through the intake passage and guides the air to the intake duct, thereby increasing the energy efficiency of the clothes dryer.

Specifically, the preheating member may have the following characteristics.

And a flow switching unit for guiding the air passing through the heat exchange space of the preheating unit to an air intake port through which the air is introduced into the intake duct, in order to form the heat exchange space.

One side of the preheating part is extended to the heating part mounting position, so that the efficiency of air preheating using the heat energy lost in the heating part can be enhanced.

One or more air inflow holes may be formed in the preheating portion, and the preheating portion may include a drum adjacent portion having at least one surface on which the at least one air inflow hole is formed, which is adjacent to the outer circumferential surface of the drum.

Accordingly, the intake air flow path includes a first intake flow path through which air introduced into the cabinet bottom surface passes through the heat exchanger and flows into the intake duct, and air introduced into the rear surface of the cabinet flows into the air intake hole, And a second intake flow path through which the refrigerant flows.

The air flowing through the first intake passage passes through the heat exchanger and is subjected to first heat exchange with air flowing through the exhaust passage, and second heat exchanges while flowing through the preheater, and then introduced into the intake duct.

The air flowing through the second intake passage may be subjected to primary heat exchange with the heat radiated from the drum, and may be introduced into the intake duct after secondary heat exchange while flowing through the preheater.

Meanwhile, the flow switching unit may be positioned at a predetermined distance forward from the air inlet, and may be formed to face the air inlet.

The preheating portion and the flow switching portion are formed integrally with each other, so that the heat energy dissipated by the heating portion can be minimized.

Meanwhile, the clothes dryer of the present invention is another method for recovering heat that is discarded. The heat exchanger is provided inside the exhaust duct and the air introduced through the exhaust duct is used to preheat the air to be dried.

The heat exchanger may be provided with a second directional flow in which a first directional flow through the intake passage guided to the drum by the air inside or outside the cabinet and an exhaust flow passage through which air discharged from the drum flows may be formed have.

The first directional flow and the second directional flow may intersect with each other at a predetermined angle.

As a result, heat exchange occurs between the air flowing in the intake passage and the exhaust passage in the heat exchanger, and the air flowing in the intake passage is preheated by the heat radiated from the air flowing in the exhaust passage, .

An air inlet is provided at the lower surface of the exhaust duct opposite to the bottom of the cabinet. Air is introduced into the lower surface of the cabinet. The upper surface of the exhaust duct is spaced apart from the lower surface of the exhaust duct by a predetermined distance An air outlet through which one air is discharged can be provided.

At this time, an opening portion through which the air outside the cabinet can be introduced into the cabinet is formed on the bottom surface of the cabinet, so that the outside air introduced through the opening portion can flow to the preheating member through the exhaust duct.

As a result, the resistance of the flow path of the air flowing into the intake duct is reduced, so that the motor load for generating the air flow can be reduced and the power consumption can be reduced.

According to another aspect of the present invention, there is provided a clothes dryer including a cabinet, a drum provided inside the cabinet to provide a space for accommodating laundry, an exhaust duct for discharging air discharged from the drum to the outside of the cabinet, And an air intake duct for guiding air that has passed through the drum to the drum. The heating unit may heat the air introduced into the intake duct.

And a heat exchanger provided in the exhaust duct and including a first heat exchange space for exchanging heat between air discharged from the drum and air introduced into the exhaust duct from the inside or the outside of the cabinet.

And a preheating member for guiding the air having passed through the heat exchanger to the intake duct and forming a second heat exchange space for heat exchange with heat radiated from the intake duct through the heat exchanger and flowing into the intake duct, A clothes dryer can be provided.

At this time, the air introduced from the bottom of the cabinet may be preheated while flowing through the first heat exchange space, and may be secondarily preheated while flowing through the second heat exchange space, and may be introduced into the intake duct.

The heat exchanger is formed therein with a divided space in which a first flow of air introduced from the inside or the outside of the cabinet and a second flow of flow discharged from the drum flow respectively, The two-way flow may be formed to cross at a predetermined angle.

According to an aspect of the present invention, there is provided a clothes dryer for preventing air from generating hot air through a bottom surface of a cabinet to generate resistance to air flowing into an air intake duct for generating hot air, Can be minimized.

The clothes dryer according to an embodiment of the present invention absorbs heat energy of hot air discharged from the drum through the bottom of the cabinet, and is guided to the intake duct after being preheated, thereby improving the energy efficiency of the clothes dryer.

The clothes dryer according to an embodiment of the present invention can improve the energy efficiency of the clothes dryer by providing space for heat exchange with the air sucked into the heat exchanger provided inside the exhaust duct and the air exhausted at predetermined angles.

The clothes dryer according to an embodiment of the present invention maximizes heat exchange efficiency by forming a heat exchange space in which air to be sucked and air to be exhausted vertically cross each other in a heat exchanger provided in an exhaust duct.

The clothes dryer according to an embodiment of the present invention can minimize the loss of heat energy by preheating the air introduced into the intake duct by using the heat loss generated in the hot air generation process.

In addition, the clothes dryer according to an embodiment of the present invention can improve the safety by reducing the temperature of discharged air by heat-exchanging hot air discharged from the drum with air flowing into the exhaust duct.

In the clothes dryer according to an embodiment of the present invention, as the inflow path of air for generating hot air is shortened, the flow path resistance is reduced, and the driving time of the motor for driving the fan is reduced, so that the power consumption of the motor can be reduced .

The clothes dryer according to an embodiment of the present invention can recover heat lost in the hot air generation process and the discharge process and convert the heat into energy for preheating the air to generate hot air, thereby providing a clothes dryer with improved energy efficiency.

1 is a perspective view of a clothes dryer according to an embodiment of the present invention.
2 is a side cross-sectional view of a clothes dryer according to an embodiment of the present invention.
3 is a perspective view of a clothes dryer according to another embodiment of the present invention.
4 is a side cross-sectional view of a clothes dryer according to another embodiment of the present invention.
5 is a perspective view showing an exhaust duct, a preheating member, and an intake duct according to the present invention.
6 is a cross-sectional view taken along the line B-B 'in FIG.
7 is a side cross-sectional view of a clothes dryer according to a modification of another embodiment of the present invention.
8 is a perspective view of a heat exchanger according to the present invention.

Hereinafter, a clothes dryer according to the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings illustrate exemplary embodiments of the present invention and are provided to explain the present invention in detail.

In addition, the same or corresponding components are denoted by the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. For convenience of explanation, the size and shape of each constituent member shown may be exaggerated or reduced have.

On the other hand, terms including an ordinal number such as a first or a second may be used to describe various elements, but the constituent elements are not limited by the terms, and the terms may refer to a constituent element from another constituent element It is used only for the purpose of discrimination.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, components of a clothes dryer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a clothes dryer according to an embodiment of the present invention, and FIG. 2 is a side sectional view of the clothes dryer of FIG. 1.

Referring to FIG. 1, a clothes dryer 100 according to the present invention includes a front cover 112, a side cover (not shown), a rear cover 113, and a top cover 111, And a drum 120 installed in the cabinet 110. The cabinet 110 includes a cabinet 110,

The base 114 and the rear cover 113 forming the bottom surface of the cabinet 110 may be formed with openings 117 and 118 through which air can flow into the cabinet 110.

The drum 120 is rotatably installed in the cabinet 110 and can receive laundry to be dried.

The clothes dryer 100 includes a door 115 mounted on the front cover 112 for opening and closing an opening of the drum 120 and various buttons provided on the front cover 112 for inputting a drying condition, And a control panel 116 having a plurality of control buttons.

The drum 120 may have a hollow cylinder shape in which a front end portion and a rear end portion are opened. The drum 120 is supported by a front supporter 121 installed at a front portion of the cabinet 110 and a rear supporter 122 installed at a rear portion of the cabinet 110 do.

At this time, although the drum 120 rotates, the front supporters 121 and the rear supporters 122 do not rotate in a fixed state inside the cabinet 110. That is, the front supporter 121 and the rear supporter 122 are stopped, while the drum 120 is relatively rotatably supported by these stationary supporters.

An exhaust duct 130 is connected to the front supporter 121. One end of the exhaust duct 130 is connected to the front supporter 121 so as to communicate with the drum 120. The other end of the exhaust duct 130 is connected to the cabinet 110, As shown in FIG.

A filter 131 may be further provided at a connection portion between the front supporter 121 and the exhaust duct 130 to filter the air exhausted from the drum 120 after drying.

A blowing fan 140 is installed in the exhaust duct 130 and the blowing fan 140 is directly connected to the motor 150 to blow air inside the drum 120 through the exhaust duct 130 to the cabinet 140. [ (Not shown).

The pressure inside the drum 120 is lowered by the rotation of the air blowing fan 140 and naturally the air outside the cabinet 110 is blown into the bottom opening 118 or the rear surface 118 formed in the base 114 of the cabinet 110. [ And then flows into the cabinet 110 through the rear opening 117 formed in the cover 113. [

1, conventionally, the hot and humid hot air discharged from the drum 120 is directly discharged to the outside of the cabinet 110 through the exhaust duct 130, thereby reusing the heat energy of the exhausted air There was no problem.

The clothes dryer 100 according to an embodiment of the present invention is provided with a heat exchanger 200 inside the exhaust duct 130 in order to reuse the heat energy discharged to the outside of the cabinet 110 through the exhaust duct 130 .

The drying air is blown into the drum 120 by the blowing fan 140 and then discharged to the outside of the cabinet 110. [ A heat exchanger 200 for recovering the sensible heat of the humid air can be installed.

The heat exchanger 200 is installed in the cabinet 110 so that the air flowing through the bottom opening 118 formed in the base 114 of the cabinet 110 and the high temperature and high humidity air discharged from the drum 120 can flow, A space for heat exchange between the respective flows can be formed.

Specifically, the heat exchanger 200 is provided with a divided space in which a first directional flow of air introduced from the inside or the outside of the cabinet 110 and a second directional flow of air discharged from the drum 120 respectively flow As shown in FIG.

That is, the first directional flow through the heat exchanger 200 and the second directional flow of the air discharged from the drum 120 are such that the air introduced from the bottom opening 118 or the rear opening 117 passes through the heat exchanger 200, Heat exchange may occur while flowing through the divided spaces provided in the heat exchanger 200.

At this time, the first directional flow and the second directional flow that flow through the heat exchanger 200 may intersect at a predetermined angle. More specifically, the first directional flow and the second directional flow may be orthogonal within the heat exchanger 200.

An air inlet 132 through which air flows in from the outside of the exhaust duct 130 may be provided on a lower surface of the exhaust duct 130 formed opposite to the base 114 of the cabinet 110.

The air inlet 132 may be formed to correspond to a position of the bottom opening 118 formed in the bottom of the cabinet 110 to reduce the air resistance introduced from the outside of the cabinet 110. The air inlet 132 of the exhaust duct 130 may be formed to have a size corresponding to the outer circumferential surface of the opening 117 formed in the base 114 of the cabinet 110. The size of the outer circumferential surface of the opening 117 It may be formed larger.

Further, a bottom filter 119, which is provided between the air inlet 132 and the bottom surface of the cabinet 110, filters the air introduced into the bottom opening 118 may be further provided.

The air introduced into the air inlet 132 flows into the cabinet 110 through the bottom opening 118 formed in the bottom of the cabinet 110 so that the air outside the cabinet 110 flows directly into the rear cover 113 of the cabinet 110, Air flowing in the cabinet 110 through the rear opening 117 formed in the cabinet 110 may be introduced.

The upper surface of the exhaust duct 130, which is formed at a predetermined distance from the lower surface of the exhaust duct 130 in the height direction of the cabinet 110, A discharge port 133 may be formed.

The air discharge port 133 is formed in such a manner that the air introduced into the air inlet 132 of the exhaust duct 130 passes through the heat exchanger 200 provided in the exhaust duct 130, And it is preferable that it is formed larger.

That is, the first directional flow flowing in the space partitioned inside the heat exchanger 200 may be a flow that flows into the air inlet 132 of the exhaust duct 130 and is discharged to the air outlet 133 have.

Also, the second directional flow may be a flow discharged from the drum 120 and discharged to the outside of the cabinet 110.

Meanwhile, the motor 150 includes two rotating shafts, and one of the rotating shafts may be connected to the blowing fan 140 to drive the blowing fan 140.

The other rotation axis of the motor 150 is coupled to a pulley 160 connected to the drum 120 and the belt 161 to rotate the pulley 160 to rotate the drum 161 120 can be rotated.

At this time, the motor for driving the blowing fan 140 and the motor for rotating the drum 120 may be separately provided.

The motor 150 for driving the blowing fan 140 has a large flow resistance due to suction of air through the rear opening 117 formed in the rear cover 113 of the cabinet 110, (150) is overloaded.

However, according to the embodiment of the present invention, as shown in FIG. 2, when the air is directly sucked through the bottom opening 118 formed in the base 114 of the cabinet 110, ) Load can be reduced.

One end of the intake duct 170 is connected to the rear supporter 122 through a hot air supply port 123 formed in the rear supporter 122. The rear supporter 122 is connected to the intake duct 170, So that hot air can be supplied to the drum 120.

The other end of the intake duct 170 may be provided with an air inlet 171 for sucking air to supply hot air to the drum 120.

A heating unit 180 for heating the air may be installed at the end of the intake duct 170.

The heating unit 180 heats the air introduced into the intake duct 170 and supplies hot air of high temperature to the drum 120. At this time, the heating unit 180 may be installed adjacent to the air inlet 171 through which the air is introduced into the intake duct 170.

The heating unit 180 may be a resistance coil heater using electric resistance heat or a burner that generates heat by burning gas.

The heating unit 180 generates heat at a temperature higher than a predetermined temperature for heating the introduced air and generates heat by flowing air around the heating unit 180 by conduction or convection of heat generated in the heating unit 180 Heat transfer occurs.

At this time, the heat transmitted to the air surrounding the heating unit 180 not only generates hot air but also can be partially radiated to the outside of the intake duct 170.

Meanwhile, the first directional flow passing through the heat exchanger 200 and discharged to the air discharge port 133 may be introduced into the intake duct 170.

At this time, the first directional flow may be heat-exchanged with the heat radiated from the intake duct 170 while flowing through the outer peripheral surface of the intake duct 170.

That is, the first directional flow passes through the heat exchanger 200 and is subjected to the first heat exchange with the second directional flow, and then flows into the intake duct 170 and the heat radiated from the intake duct 170, Heat-exchanged and preheated, and then introduced into the intake duct 170.

In order to increase the energy efficiency by reusing the heat dissipated and lost to the outside of the intake duct 170, a preheating (not shown) spaced from the outer circumferential surface of the intake duct 170 to surround the intake duct 170 Member 190 may be further provided.

Hereinafter, a clothes dryer according to another embodiment of the present invention having a preheating member will be described in detail with reference to FIGS. 3 to 6. FIG.

FIG. 3 is a perspective view of a clothes dryer according to another embodiment of the present invention, and FIG. 4 is a side sectional view of the clothes dryer of FIG. 1. FIG. 5 is a perspective view showing an exhaust duct, an intake duct, and a preheating member according to another embodiment of the present invention, FIG. 6 is a sectional view taken along the line B-B ' Lt; / RTI >

First, the flow of the exhaust duct, the intake duct, the preheating member, and the air of the present invention will be described in detail.

A detailed description of the components of the clothes dryer 100 described above will be omitted.

The clothes dryer 100 according to another embodiment of the present invention includes a cabinet 110, a drum 120 provided in the cabinet 110 to provide a space for accommodating laundry, And a heating unit 180 for heating the air introduced into the intake duct 170. The intake duct 170 may be formed of a metal plate,

Further, the drum 120 may include an exhaust duct 130 for forming a passage through which air is discharged.

An exhaust duct in which air discharged from the drum 120 is discharged to the outside of the cabinet 110 through the exhaust duct 130 and air in or out of the cabinet 110 are accommodated in the cabinet 110, And an intake passage guided to the drum 120 may be formed.

A heat exchanger 200 is provided on the exhaust passage so that heat exchange can be performed between air discharged from the heat exchanger 200 to the exhaust passage and air introduced into the intake passage.

The air passing through the heat exchanger 200 is guided to the intake duct 170 and the air flowing through the heat exchanger 200 to the intake duct 170 flows from the intake duct 170 And a preheating member 190 for forming a heat exchange space for heat exchange with heat to be radiated.

The preheating member 190 may form a space for heat exchange between the air flowing through the preheating member 190 and the heat radiated from the intake duct 170. Accordingly, by reusing the heat discharged through the intake duct 170, the air flowing through the preheating member 190 is preheated, thereby improving the energy efficiency of the dryer.

The preheating member 190 may be fixed to the top of the exhaust duct 130. The air introduced into the air inlet 132 formed on the lower surface of the exhaust duct 130 passes through the heat exchanger 200 and then flows into the air discharge port 133 formed on the upper surface of the exhaust duct 130. [ And may be introduced into the preheating member 190.

Meanwhile, the heat exchanger 200 may be provided with a divided space in which a first directional flow flowing through the intake passage and a second directional flow flowing through the exhaust passage flow respectively.

The first directional flow and the second directional flow that flow in the divided space formed in the heat exchanger 200 may cross at a predetermined angle.

The first directional flow is a flow that is introduced into the air inlet 132 of the exhaust duct 130 and then discharged to the air outlet 133 through the bottom opening 118 of the cabinet 110, (H), that is, in the vertical direction of the flow path 110.

The second directional flow may be a flow in the longitudinal direction L of the cabinet 110, that is, a horizontal flow, which is discharged from the drum 120 and discharged to the outside of the cabinet 110.

Accordingly, the first direction flow and the second direction flow may intersect at right angles. If the first directional flow and the second directional flow are orthogonal, heat exchange efficiency in the heat exchanger 200 can be maximized. This is because the same effect is obtained as the heat exchanging area is widened.

Hereinafter, the intake passage and the exhaust passage will be described in more detail.

As described above, in the cabinet 110, the air exhausted from the drum 120 is exhausted to the outside of the cabinet 110 through the exhaust duct 130, Or an intake passage through which external air is guided to the drum 120 can be formed.

The intake passage is a passage through which air is introduced and preheated to generate hot air for drying and then heated to flow to the drum.

The air introduced through the bottom opening 118 enters the air inlet 132 formed in the lower surface of the exhaust duct 130 or the air introduced into the rear opening 117 flows into the cabinet 110, An air inflow path through which air flows into the air inflow portion 132 can be formed.

And a plurality of first heat exchange passages formed in the heat exchanger 200 as a rear end of the air inflow passage and performing heat exchange with air discharged from the drum 120 while air flowing into the exhaust duct 130 flows .

The air passing through the heat exchanger 200 is guided to the rear end of the first heat exchanging flow passage by the preheating member 190 located above the exhaust duct 130 and is heat-exchanged with the heat radiated from the preheating member 190 A second heat exchange passage guided to the intake duct 170 may be formed.

The air introduced into the intake duct 170 flows into the intake duct 170 through the second heat exchange channel and flows through the intake duct 170. The air introduced into the intake duct 170 passes through the heating unit 180, And a hot air flow path that is guided to the drum 120 by hot air can be formed.

Accordingly, the intake passage is formed by an air inflow passage, a first heat exchanging passage, a second heat exchanging passage, and a hot air moving passage, and the air introduced into the intake passage sequentially flows through the passage to be guided to the drum 120 .

Meanwhile, the exhaust passage is a passage through which the hot air, which has been dried in the drum 120, is discharged to the outside of the cabinet 110. Specifically, the exhaust passage may include the following passage.

The exhaust passage may be formed in the exhaust duct 130, and a first exhaust passage through which hot and humid air exhausted from the drum 120 flows may be formed.

The first exhaust passage is formed at the rear end of the heat exchanger 200. The high temperature and high humidity air discharged from the drum 120 flows and flows through the intake passage formed in the heat exchanger 200 A plurality of heat-releasing passages for releasing heat can be formed.

At this time, the first heat exchange passage of the intake passage and the heat release passage of the exhaust passage are alternately formed in the heat exchanger 200, so that heat exchange efficiency can be increased.

The first directional flow flowing through the intake passage formed in the heat exchanger 200 and the second directional flow flowing through the exhaust passage may be formed to intersect with each other at a predetermined angle. The first directional flow and the second directional flow are preferably at right angles. When the first directional flow and the second directional flow are orthogonal, the heat exchange area between the first directional flow and the second directional flow increases, and heat exchange can be performed quickly.

A second exhaust passage may be formed at a rear end of the heat-releasing passage, through which heat is taken while passing through the heat-releasing passage, and air whose temperature is lowered is discharged to the outside of the cabinet 110.

Accordingly, the exhaust passage is formed with a first exhaust passage, a heat-releasing passage, and a second exhaust passage, and the air discharged through the exhaust passage flows sequentially through the passage and can be discharged to the outside of the cabinet 110.

The preheating member 190 may include a preheating unit 191 spaced apart from the intake duct 170 by a predetermined distance and surrounding the intake duct 170, To the air intake port (171) of the intake duct (170).

The preheating unit 191 is configured to surround the intake duct 170 to form a flow space through which the air passing through the heat exchanger 200 can flow along the outer circumferential surface of the intake duct 170 .

At this time, a heat exchange space is formed in the preheating unit 191 for heat exchange by the heat radiated from the intake duct 170. Air flowing through the preheating unit 191 flows through the heat exchange space, 170 to recover heat lost to the outside of the heat exchanger.

The preheating unit 191 may extend from the end of the air inlet 171 in the longitudinal direction L of the cabinet 110 to a position of the heating unit 180. This makes it possible to more effectively form the heat exchange space for preheating the air flowing through the preheating unit 191 by allowing the preheating unit 191 to cover the entire heating unit 180.

An opening having a shape and a size corresponding to the air outlet 133 of the exhaust duct 130 may be formed on the lower surface of the preheater 191 so that the air passing through the heat exchanger 200 may be introduced, It can be formed in an open shape.

The flow switching unit 192 of the preheater 190 switches the air flow direction so that air having passed through the preheating unit 191 flows into the air inlet 171 of the intake duct 170 .

The flow switching unit 192 is spaced a predetermined distance forward of the air suction port 171 and may be formed to face the air suction port 171.

The preheating unit 191 and the flow switching unit 192 may be formed separately from each other but may be integrally formed to prevent diffusion of heat energy dissipated to the outside of the intake duct 170. That is, the preheating member 190 may be formed as a cylinder or a polyhedron with one side opened.

In order to reduce the flow resistance when the direction of the flow from the preheater 191 to the flow switching unit 192 is switched, the connection unit to which the preheating unit 191 and the flow switching unit 192 are connected is inclined Or may be formed to have a curvature.

Hereinafter, a modified example of the preheating member will be described in detail with reference to FIG. 7 is a side sectional view of a clothes dryer showing a modification of another embodiment of the present invention.

7, the preheating unit 191 of the preheating member 190 is provided with one or more air inflow holes (not shown) for guiding the air introduced into the rear opening 117 of the cabinet 110 into the inside of the preheating member 190, (193) may be formed.

The air inlet holes 193 may be formed in a horizontal direction or a vertical direction in a flow direction of air flowing through the preheating unit 191.

The air introduced into the rear opening 117 of the cabinet 110 flows through the cabinet 110 and absorbs heat discharged to the outer circumferential surface of the drum 120 during the drying process, Lt; RTI ID = 0.0 > 193 < / RTI >

Accordingly, at least one surface of the preheating portion 191, in which the at least one air inflow hole 193 is formed, may be provided adjacent to the outer circumferential surface of the drum 120.

That is, at least one surface of the preheating member 190 is provided adjacent to the drum 120 so that the air heated by the heat emitted from the drum 120 can be more easily introduced into the preheating unit 191 desirable.

At this time, the drum adjacent portion 191a of the preheating unit 191 provided adjacent to the drum 120 may be installed at a predetermined distance from the drum 120. [

That is, the drum adjacent portion 191a is preferably formed at a minimum distance that does not interfere with the rotational motion of the drum 120. [

The drum adjacent portion 191a may be formed as a curved surface having the same radius of curvature as that of the drum 120 and may be formed to face the outer circumferential surface of the drum 120. [

At least one air guide 194 may be installed on the outer surface of the preheating unit 191 to guide the air to the at least one air inflow hole 193 to facilitate air inflow.

This can reduce the flow resistance of the air flowing into the preheating member 190 and reduce the flow loss.

One side of the air guide 194 is fixed at a position adjacent to the air inlet hole 193 on the outer surface of the preheater 191 and the other side is open at an angle to the upper side of the air inlet hole 193 And may be formed in an arc shape.

At this time, it is preferable that the air guide 194 is formed in the at least one air inflow hole 193.

The air introduced into the rear opening 117 of the cabinet 110 absorbs the heat radiated to the outer circumferential surface of the drum 120, And can be introduced into the air inlet hole 193.

The air introduced into the preheating member 190 through the air inflow hole 193 flows through the heat exchange space formed in the preheater member 190 and is further preheated by heat exchange with heat emitted from the intake duct 170, The flow direction of the refrigerant can be changed in the switching portion 192 and flowed into the intake duct 170.

Hereinafter, the process of heat exchange in the exhaust duct, the intake duct, and the preheating member of the present invention will be described in detail with reference to FIG. 3 to FIG.

A ventilation fan 140 for exhausting the air inside the drum 120 and an air blown out from the outside of the cabinet 110 to the inside of the exhaust duct 130 are provided in the inside of the exhaust duct 130, A heat exchanger 200 including a first heat exchange space S1 for performing heat exchange with sensible heat of air discharged from the heat exchanger 200 may be provided.

The preheating member 190 guides the air that has passed through the heat exchanger 200 to the intake duct 170 and the air that flows into the intake duct 170 through the heat exchanger 200 is introduced into the preheater And a second heat exchange space S2 for exchanging heat with heat radiated from the intake duct 170 while flowing through the intake ducts 190.

The air introduced from the bottom of the cabinet 110 is firstly preheated while flowing through the first heat exchange space S1 and is secondarily preheated while flowing through the second heat exchange space S2, And can be introduced into the air inlet 171.

Hereinafter, the heat exchanger of the present invention will be described in detail with reference to FIG. 8 is a perspective view showing a heat exchanger 200 according to the present invention.

The heat exchanger 200 of the present invention is provided with a heat exchanging unit 200 for exchanging heat between the air introduced through the bottom opening 118 formed in the base 114 of the cabinet 110 and the high temperature and high humidity air discharged from the drum 120, A plurality of flow paths may be formed.

That is, the heat exchanger 200 is provided with a first direction flow I flowing from the bottom surface of the cabinet 110 toward the intake duct 170 and a second direction I flowing from the drum 120 toward the second direction A flow II can be formed.

As shown in FIG. 8, the heat exchanger 200 of the present invention may be formed by alternately stacking a plurality of tubes 210 and a fin structure 220. The heat exchanger 200 may further include a front cover 230 surrounding the front end and a rear cover 240 surrounding the rear end.

The tube 210 may have a duct structure having both open ends and a rectangular cross section and may form a flow path of the second direction flow II through which the air discharged from the drum 120 flows.

In addition, the fin structure 220 may form a channel through which the air can flow by bending the metal plate in a zigzag fashion. The pin structure 220 may be formed by bending a metal plate and repeating a bone and a bone. For example, the fin structure 220 may have a continuous cross-section in the longitudinal direction L and may have a continuous cross-section.

Accordingly, the valleys generated by the above-described method can form a flow path of the first directional flow I through which the air flowing from the bottom surface of the cabinet 110 flows.

Each of the tubes 210 and the fin structure 220 is repeatedly laminated to form a single heat exchanger 200. By forming such a repetitive lamination structure, the first directional flow I ) And the second directional flow (II) can be increased.

The tube 210 and the fin structure 220 may be stacked in the width direction W of the exhaust duct 130 as shown in FIG.

The second directional flow II is formed in the longitudinal direction L of the exhaust duct 130 discharged from the drum 120 and flowing through the tube 210, The air flowing from the bottom surface of the cabinet 110 may flow in the height direction H of the exhaust duct 130 through which the fin structure 220 flows.

At this time, the first directional flow I and the second directional flow II may be formed such that the flow direction crosses vertically, and the flow direction crosses at a predetermined angle. As a result, the contact area where the heat transfer between the first direction flow I and the second direction flow II is generated is widened and the heat exchange efficiency can be increased.

Hereinafter, the operation of the clothes dryer of the present invention will be schematically described again.

The air introduced through the bottom opening 118 formed in the bottom of the cabinet 110 is guided to the exhaust duct 130 through the air inlet 132 formed in the lower surface of the exhaust duct 130. [ 130) through the heat exchanger (200).

The heat exchanger 200 has a structure in which a tube 210 and a fin structure 220 are stacked so that the tube 210 in which hot air discharged from the drum 120 flows and the tube 210, Heat exchange occurs between the fin structures 220 through which the air flowing from the bottom flows.

At this time, sensible heat radiated from the air flowing through the tube 210 can be absorbed by the air flowing through the fin structure 220 to be preheated.

The air preliminarily preheated through the heat exchanger 200 is discharged through the air discharge port 133 of the exhaust duct 130 and flows into the intake duct 170 having the heating unit 180 therein .

A heat preheating member 190 is provided to surround the intake duct 170 at a predetermined distance from the intake duct 170 to enhance the heat exchange efficiency with the heat radiated from the intake duct 170.

The air introduced through the rear opening 117 formed on the rear surface of the cabinet 110 flows into the interior of the warming member 190 through the air inflow hole 193 formed in the preheating member 190, .

At this time, the air introduced through the rear opening 117 absorbs the heat radiated to the outer circumferential surface of the drum 120 during the drying process in the drum 120, and is preliminarily preheated and then introduced into the preheating member 190 Can be introduced.

The air introduced into the preheating member 190 passes through the preheating unit 191 of the preheating member 190 and flows from the heating unit 180 installed in the intake duct 170 to the outside of the intake duct 170 And can be further preheated by absorbing additional heat energy.

The air having passed through the preheating unit 191 flows into the air inlet 171 of the intake duct 170 by the flow switching unit 192.

The air introduced into the air intake port 171 passes through the heating unit 180 installed in the intake duct 170 and is supplied to the drum 120 as hot air at a high temperature.

At this time, since the air passing through the heating unit 180 is sufficiently preheated, the heating time for generating the hot air at a high temperature is much shorter.

Further, energy consumption required for operation of the apparatus for generating hot air can be reduced, and a clothes dryer having high energy efficiency can be provided.

On the other hand, the drum 120 is rotated by the operation of the motor 150, and the drying object in the drum 120 is dried by contact with the supplied hot air while repeating rising and falling.

The hot and humid air in the drum 120 passes through the exhaust duct 130 by the blowing fan 140 and is discharged to the outside of the cabinet 110 through the heat exchanging process in the heat exchanger 200.

At this time, the air that has undergone the heat exchange process in the heat exchanger 200 is discharged to the outside of the cabinet 110 in a state where the temperature is reduced, thereby improving the safety.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

100: Clothes dryer 110: Cabinet
117: bottom opening 118: rear opening
120: Drum 130: Exhaust duct
140: blower fan 150: motor
160: pulley 170: intake duct
171: air inlet port 180: heating section
190: preheating member 191: preheating member
192: flow switching unit 200: heat exchanger
210: tube 220: pin structure
230: Front cover 240: Rear cover

Claims (28)

cabinet;
A drum provided inside the cabinet to provide a space for accommodating laundry;
An intake duct for supplying hot air to the drum;
A heating unit provided in the intake duct to heat the air flowing into the intake duct;
An exhaust duct through which air is discharged from the drum; And
Wherein a partition space is provided inside the exhaust duct for partitioning the flow of the first direction of the air introduced from the inside or the outside of the cabinet and the flow of the second direction of the air discharged from the drum into the inside of the exhaust duct, And a heat exchanger in which heat exchange occurs between the directional flow and the second directional flow,
Wherein the first directional flow and the second directional flow that flow inside the heat exchanger intersect at a predetermined angle. The method according to claim 1,
Further comprising a preheating member for guiding the air having passed through the heat exchanger to the intake duct and forming a heat exchange space for heat exchange with heat that passes through the heat exchanger and air flowing into the intake duct is dissipated from the intake duct. 3. The method of claim 2,
Wherein the preheating member is fixed to the top of the exhaust duct. 3. The method according to claim 1 or 2,
An air inlet for introducing air into the lower surface of the exhaust duct formed opposite to the bottom of the cabinet,
Wherein an air discharge port through which the air having passed through the heat exchanger is discharged is formed on an upper surface of an exhaust duct formed at a predetermined distance in a height direction from a lower surface of the exhaust duct. 5. The method of claim 4,
Wherein the first directional flow is a flow in a direction in which the air introduced into the air inlet port is discharged to the air discharge port. 6. The method of claim 5,
Wherein the first directional flow passes through the heat exchanger, performs a first heat exchange with the second directional flow, and then is preheated by secondary heat exchange with heat radiated from the intake duct while flowing to the intake duct. 3. The method according to claim 1 or 2,
Wherein the first directional flow and the second directional flow are orthogonal. cabinet;
A drum provided inside the cabinet to provide a space for accommodating laundry;
An intake duct for forming a flow path for supplying hot air to the drum;
A heating unit for heating the air introduced into the intake duct;
And an exhaust duct forming a flow path through which air is discharged from the drum,
An exhaust passage for exhausting air discharged from the drum to the outside of the cabinet through the exhaust duct and an intake passage for guiding the air inside or outside the cabinet to the drum are formed in the cabinet,
Wherein a heat exchanger is provided on the exhaust flow path so that heat exchange occurs between air discharged from the heat exchanger to the exhaust flow path and air introduced into the intake flow path. 9. The method of claim 8,
And a preheating member for guiding the air having passed through the heat exchanger to the intake duct and forming a heat exchange space for heat exchange with heat that passes through the heat exchanger and air flowing into the intake duct is dissipated from the intake duct. 10. The method of claim 9,
Wherein the preheating member is fixed to the top of the exhaust duct. 9. The method of claim 8,
An air inlet for introducing air into the lower surface of the exhaust duct formed opposite to the bottom of the cabinet,
Wherein an air discharge port through which the air having passed through the heat exchanger is discharged is formed on an upper surface of an exhaust duct formed at a predetermined distance in a height direction from a lower surface of the exhaust duct. 10. The method according to claim 8 or 9,
In the heat exchanger,
Wherein the first directional flow and the second directional flow form a divided space in which a first directional flow flowing in the intake passage and a second directional flow flowing in the exhaust passage flow respectively, And the clothes dryer. 10. The method of claim 9,
Wherein the preheating member includes a preheating portion configured to surround the intake duct to form the heat exchange space. 14. The method of claim 13,
And one side of the preheating part extends to the heating part installation position. 14. The method of claim 13,
Wherein at least one air inflow hole is formed in the preheating portion. 16. The method of claim 15,
Wherein the preheating portion includes a drum adjacent portion where at least one surface of the at least one air inflow hole is formed adjacent to the outer circumferential surface of the drum. 17. The method of claim 16,
Wherein the intake air flow path includes a first intake passage through which air introduced into a bottom surface of the cabinet passes through the heat exchanger and flows into the intake duct and a second intake passage through which air introduced into a rear surface of the cabinet flows into the air intake hole, And a second intake air flow path formed in the second air intake passage. 18. The method of claim 17,
The air flowing through the first intake passage passes through the heat exchanger and performs primary heat exchange with air flowing through the exhaust passage. The air flows into the preheater while being subjected to secondary heat exchange and then flows into the intake duct.
Wherein the air flowing through the second intake passage is subjected to first heat exchange with heat radiated from the drum, and second heat exchange while flowing through the preheater, and then flows into the intake duct. 14. The method of claim 13,
Wherein the preheating member further comprises a flow switching unit for guiding the air that has passed through the heat exchange space of the preheating unit to an air inlet formed at one end of the intake duct. 20. The method of claim 19,
Wherein the flow switching unit is spaced forward from the air inlet by a predetermined distance. 21. The method of claim 20,
And the flow switching portion is formed to face the air inlet. 20. The method of claim 19,
Wherein the preheating part and the flow switching part are integrally formed. 9. The method of claim 8,
Wherein an opening is formed in a bottom surface of the cabinet so that air outside the cabinet can be introduced into the cabinet. cabinet;
A drum provided inside the cabinet to provide a space for accommodating laundry;
An exhaust duct for discharging the air discharged from the drum to the outside of the cabinet;
An air intake duct for guiding air passing through the exhaust duct to the drum;
And a heating unit for heating the air introduced into the intake duct,
A heat exchanger provided in the exhaust duct and including a first heat exchange space for exchanging heat between air discharged from the drum and air introduced into the exhaust duct from inside or outside the cabinet; And
And a second heat exchange space for guiding the air having passed through the heat exchanger to the intake duct and for exchanging heat with heat radiated from the intake duct through air passing through the heat exchanger and flowing to the intake duct Features a clothes dryer. 25. The method of claim 24,
An air inlet for introducing air into the lower surface of the exhaust duct formed opposite to the bottom of the cabinet,
Wherein an air discharge port through which the air having passed through the heat exchanger is discharged is formed on an upper surface of an exhaust duct formed at a predetermined distance in a height direction from a lower surface of the exhaust duct. 26. The method of claim 25,
Wherein an opening is formed in a bottom surface of the cabinet so that air outside the cabinet can be introduced into the cabinet. 25. The method of claim 24,
Wherein air introduced from the inside or the outside of the cabinet flows through the first heat exchange space and is first preheated and flows into the second heat exchange space while being secondarily preheated and flows into the intake duct. 25. The method of claim 24,
Wherein the heat exchanger is formed with a divided space in which a first flow of the air introduced from the inside or the outside of the cabinet and a second flow of flow discharged from the drum respectively flow therein, Wherein the flow is formed to cross at a predetermined angle.

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