KR101740438B1 - drying device - Google Patents

Abstract

The present invention relates to a dryer having optimized heat flow and temperature distribution from a heater, comprising: a cabinet; A drum rotatably coupled to the inside of the cabinet to receive an object to be dried; A supply duct for guiding hot air to the drum; And a heater installed inside the supply duct, wherein a hot air guide member is installed in the supply duct.

Description

Dryer {drying device}

The present invention relates to a dryer, and more particularly to a dryer in which heat flow from a heater and temperature distribution are optimized.

The clothes processing apparatus usually includes a washing machine for washing laundry and a dryer for drying the laundry.

The dryer is a home appliance in which laundry, which is normally laundered, is dried by using high-temperature air. Generally, the dryer has a laundry accommodating portion for accommodating the laundry. Drying air is supplied to the laundry accommodating portion and the humid air in the laundry accommodating portion is exhausted to dry the laundry.

The dryer can be divided into a top loading method and a front loading method depending on the method of putting the laundry into the dryer. In the top loading method, the laundry is loaded from the top of the dryer, while in the front loading method, the laundry is loaded from the front of the dryer.

Such a dryer may also be divided depending on the type of laundry receiving portion in which the laundry is received. For example, there are cabinet type dryers and drum type dryers.

In the cabinet type dryer, the laundry is hung inside the laundry receiving portion through a hanger or the like, or is laid through a shelf or the like.

The drum type dryer includes a drum for receiving laundry, a driving source for driving the drum, a heating means such as a heater for heating the air flowing into the drum, and a fan for sucking or discharging air in the drum. do.

Separating the dryer in another way can be divided into a condenser dryer and an exhaust dryer.

In a condensing dryer, air in the drum is heat-exchanged with the laundry and is humidified. The air is circulated without being discharged to the outside of the dryer, and a separate condenser exchanges heat with the outside air to produce condensed water.

However, in such a conventional dryer, the outlet temperatures of the upper heater and the lower heater are different, and the temperature at the lower side of the heat distribution from the heater tends to be higher.

Therefore, it is necessary to optimize such heat flow and temperature distribution.

It is an object of the present invention to provide a dryer in which heat flow from a heater and temperature distribution are optimized.

According to an aspect of the present invention, A drum rotatably coupled to the inside of the cabinet to receive an object to be dried; A supply duct for guiding hot air to the drum; And a heater installed inside the supply duct, wherein a hot air guide member is installed in the supply duct.

The supply duct includes a bent portion bent upward from a lower portion of the drum, and the hot air guide member is provided adjacent to the bent portion.

And the hot air guide member is provided at a front end of the bent portion.

The supply duct includes a heater mounting portion disposed at an outer lower portion of the drum, the bending portion bent upward from the heater mounting portion, and a duct portion connected to the bending portion and disposed at an outer rear side of the drum .

And the hot air guide member is disposed in a vertical direction toward an upper side of the drum.

The heater is installed in the heater mounting part, and is composed of a heat wire coil and a coil supporter in which the heat wire coil is wound and supported.

And the heater is composed of an upper heater and a lower heater disposed on the upper and lower portions of the heater mounting portion, respectively.

And the heater is characterized in that more heat coil is disposed in the upper heater than in the lower heater.

And the heat coil disposed in the upper heater is at least twice as large as the heat coil disposed in the lower heater.

And the heater is characterized in that the hot wire coils are disposed in a zigzag manner.

The dryer according to an embodiment of the present invention has an effect of optimizing the heat flow and the temperature distribution from the heater by eliminating the temperature difference between the outlet end of the upper heater and the lower heater and the temperature difference inside the supply duct.

1 is a cross-sectional view of a dryer in accordance with an embodiment of the present invention.
2 is a plan view of the dryer according to Fig.
FIG. 3 is a graph showing an example of a heater outlet end temperature of the dryer according to FIG. 2;
Fig. 4 is an enlarged view showing a main part of the supply duct according to Fig. 1; Fig.
Fig. 5 is a perspective view showing a heater installation state of the supply duct according to Fig. 1; Fig.
Fig. 6 is a view showing the arrangement of the hot wire coils of the heater according to Fig. 5;
Fig. 7 is a view showing another example of the arrangement of the hot wire coils of the heater according to Fig. 5;

Hereinafter, for convenience of explanation, a condensing dryer will be described as an embodiment of the present invention, and a dryer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, a drying dryer according to an embodiment of the present invention includes a cabinet 10 having a main controller (not shown) for controlling the dryer, A front supporter rotatably supporting an open front side of the drum 20 and a rear supporter for rotatably supporting the rear side of the drum 20, A journal bearing member 24 for supporting the drum 20, and a motor 60 for rotating the drum 20.

The dryer includes a discharge duct 50 connected to the front supporter 30, a supply duct 40 connected to the rear surface of the cabinet 10 to communicate with the drum 20, A blowing fan 52 for exhausting the air inside the casing 20 and a heater 42 provided on the supply duct 40 for heating the outside air.

The dried and dehumidified air is dehumidified through the condenser 70 and the condensed water generated in the condenser 70 is drained to the outside of the cabinet 10 by the drain pump assembly 80. A cooling fan (72) and a drive motor (60) for cooling the condenser (70) are installed at one side of the condenser (70).

An opening corresponding to the opening 21a formed in the front of the drum 20 is formed in the front of the cabinet 10 and the opened portion is opened and closed by the door 15. [

The front supporter 30 and the journal bearing member 24 rotatably support the front and rear sides of the drum 20 and the front upper or lower portion of the drum 20 is rotatably supported by the rollers 90 and the like . Even when the drum 20 rotates, the front supporter 30 is fixed to the inside of the cabinet 10 without rotating.

The journal bearing member 24 is also fixed to the inside of the cabinet 10 and does not rotate so that the drum 20 rotates relative to the bearing mounted on the inside of the journal bearing member 24.

A discharge duct 50 is connected to the lower side of the front supporter 30 and a blowing fan 52 is installed in the discharge duct 50 to circulate the air inside the drum 20 after the drying is completed. One end of the discharge duct 50 is connected to the front supporter 30 and the other end is connected to the supply duct 40. The filter supporter 30 may be further provided with a filter assembly 100 for filtering the air exhausted from the drum 20 after the drying, at a connection portion between the front supporter 30 and the exhaust duct 50. The filter assembly 100 will be described later.

The air blowing fan 52 is directly connected to the motor 60 to forcibly blow air inside the drum 20.

A plurality of through holes 10a are formed in the rear of the cabinet 10 and a supply duct 40 for supplying air circulated through the discharge duct 50 to the drum 20 is connected. A cover 22 is provided between the rear inner surface of the cabinet 10 and the rear outer surface of the drum 20 so that the air supplied from the supply duct 40 can be supplied to the inside of the drum 20 Respectively.

A plurality of air holes 20b for air communication are formed in the rear of the drum 20. A through hole 10a formed in the cabinet 10 and a vent hole 20b formed in the drum 20 are formed in the cover 22, As shown in Fig.

The air introduced through the supply duct 40 can be directly introduced into the drum 20 because the through hole 10a and the air vent hole 20b are located inside the cover 22. [ A heater 42 for heating the air is provided on the supply duct 40 (the detailed structure of the supply duct and the heater will be described later).

The heater 42 heats the introduced dry air when the humid air circulated by the blowing fan 52 is dehumidified through the condenser 70, which will be described later, and then flows into the supply duct 40. The dried air is heated by the heater 42 and re-supplied to the drum 20 through the supply duct 40.

That is, when the drum 20 rotates and the air inside the drum 20 is exhausted through the exhaust duct 50 by the blowing fan 52, the air heated through the supply duct 40 flows into the drum 20 . The heater 42 is installed inside the supply duct 40 at an inlet end where the air is introduced into the supply duct 40 so that the heated air can be supplied to the drum 20 through the supply duct 40 .

The motor 60 has two rotating shafts, one of which is connected to the blowing fan 52 to drive the blowing fan 52. The other rotation axis of the motor 60 is coupled to the pulley 62 to rotate the pulley 62. Since the pulley 62 is connected to the drum 20 by the belt 64, the rotation of the belt 64 causes the drum 20 to rotate.

The condenser 70 is installed between the exhaust duct 50 and the supply duct 40 to dehumidify the humid air exhausted through the exhaust duct 50 to be supplied to the supply duct 40.

The condenser 70 may be an air-cooled or water-cooled condenser.

4, the supply duct 40 is extended from the lower side to the rear side of the drum 20 to guide the hot air into the drum 20. As shown in FIG. The supply duct 40 includes a heater mounting portion 42 positioned below the drum 20 and provided with a heater 420 therein and a bending portion 44 bent upward from the end of the heater mounting portion 42, And a duct portion 46 which is connected to the bent portion 44 and extends to the rear of the drum 20. A heater 420 is installed inside the heater mounting portion 42.

The heater 420 is composed of an upper heater 420a and a lower heater 420b and heats the air introduced into the heater installation portion 42 of the supply duct 40. The heated air passes through the heater 420, And is guided to the duct portion 46 through the bent portion 44.

The heater 420 is constituted by a coil supporting portion 422 disposed on the upper side and the lower side of the heater mounting portion 42 and a heating coil 424 supported on the coil supporting portion 422 by being wound on the coil supporting portion 422.

3, the temperature at the outlet end of the upper heater 420a (the portion adjacent to the bent portion) and the temperature at the outlet end of the lower heater 420b are different from each other even when the same position of the hot wire coil 424 is wound at the same position Difference.

For example, if the hot wire coil 424 is arranged at six places of 2400W each in the upper heater 420a and the lower heater 420b, the temperature of the lower heater 420b is lower than the outlet temperature of the upper heater 420a, The temperature at the outlet end of the reactor is high. Therefore, heat transfer from the heater 420 is performed more on the lower heater 420b than on the upper heater 420a, and the temperature on the side of the lower heater 420b is higher than the temperature on the side of the upper heater 420a.

Also, although not shown in the drawing, a temperature difference also occurs in the duct portion 46 of the supply duct 40, and the temperature of the wall surface tends to be higher than the temperature of the central portion of the duct portion 46. The flow of the hot air is also faster at the wall side than at the center of the duct portion 46 and the streamline is not formed at the center of the duct portion 46, do.

This unbalance of the heat distribution is caused by the geometrical structure of the hot wire coil 424 wound around the upper heater 420a and the lower heater 420b. In order to solve this difference in temperature distribution, the hot wind guide member 48 And the arrangement of the heat wire coils 424 of the heater 420 is optimized.

As shown in Fig. 4, the hot air guide member 48 can be positioned on the bending portion 44. As shown in Fig. Or the heater mounting portion 42 but may be located at the front end of the bent portion 44. [

The hot air guide member 48 is formed of two thin plates so as to guide the hot air toward the center of the duct portion 46. One end of the hot air guide member 48 is fixed to the inner lower end of the bent portion 44 and the other end of the hot air guide member 48 extends upward toward the center of the duct portion 46.

The air heated by the heater 420 passing through the heater mounting portion 42 is guided to the duct portion 46 while being divided into the hot air guide member 48 and the hot air guide member 48. The space between the hot air guide member 48 and the wall surface of the bent portion 44 may be narrower than the space between the hot air guide members 48 in order to guide a larger amount of hot air toward the center of the duct portion 46 have.

The hot wind guide member 48 is provided to cause the hot wind and the hot wind guide member 48 to collide with each other in the vicinity of the bent portion 44 into which hot air flows into the duct portion 46 to form turbulence, This can help to resolve the temperature difference at the outlet end.

5 and 6, the heater 420 may be provided on the upper heater 420a at a position more than the lower heater 420b in order to solve the temperature difference at the outlet end of the heater 420, (424) can be disposed.

The temperature at the outlet end of the lower heater 420b is higher than the temperature at the outlet end of the upper heater 420a when the same number of the heat coil 424 is disposed in the upper heater 420a and the lower heater 420b, 420a, more heat ray coils 424 are disposed so that the temperature difference can be eliminated and the heat flow distribution can be made uniform.

Alternatively, as shown in FIG. 7, the heater 420 may arrange the positions of the hot wire coils 424 to be wound in zigzags. That is, since the heat coil 424 is uniformly arranged in the zigzag at the upper portion, the middle portion, and the lower portion of the heater 420, the temperature at the outlet end of the heater 420 itself can be uniformly distributed, The distribution can be made uniform.

In this way, the temperature difference at the outlet end of the heater 420 is eliminated, and the uniform temperature of the hot air passing through the hot air guide member 48 can be made uniform by supplying hot air of uniform temperature. Therefore, it is possible to solve the temperature difference between the wall surface of the duct portion 46 and the central portion.

The dryer according to an embodiment of the present invention having the above-described structure has an effect of optimizing the heat flow and the temperature distribution from the heater by eliminating the temperature difference between the outlet ends of the upper and lower heaters and the inside of the supply duct have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. And such changes are within the scope of the appended claims.

10: cabinet 20: drum
40: supply duct 42: heater mounting part
44: bent portion 46: duct portion
48: hot air guide member 420: heater
420a: upper heater 420b: lower heater
422: coil support portion 424:

Claims (10)

cabinet;
A drum rotatably coupled to the inside of the cabinet to receive an object to be dried;
A heater installed in a lower portion of the drum, a bent portion bent upward from the heater mounting portion, and a duct portion connected to the bent portion and disposed on an outer rear side of the drum, Supply duct;
A heater installed inside the heater mounting portion;
And a hot air guide member having one end fixed to an inner lower end portion of the bent portion and the other end extending upward toward the duct portion in order to solve the temperature difference between the upper side and the lower side of the air supplied from the outlet end of the heater mounting portion Dryer. The method according to claim 1,
Wherein the hot air guide member is formed of two plate members spaced apart from each other. 3. The method of claim 2,
Wherein a gap between the plate member and the wall surface of the bent portion is formed to be narrower than an interval between the two spaced apart plate members. delete The method according to claim 1,
Wherein the hot air guide member is disposed in a vertical direction toward an upper side of the drum. The method according to claim 1,
Wherein the heater is installed in the heater mounting portion and comprises a heat coil and a coil supporter in which the heat coil is wound and supported. The method according to claim 6,
Wherein the heater is constituted by an upper heater and a lower heater respectively disposed on upper and lower portions of the heater mounting portion. 8. The method of claim 7,
Wherein the heater has more hot wire coils disposed in the upper heater than the lower heater. 8. The method of claim 7,
Wherein the hot wire coil disposed in the upper heater is at least twice as large as the hot wire coil disposed in the lower heater. The method according to claim 6,
Wherein the heater is arranged in a staggered arrangement of the hot wire coils.

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