KR101852425B1 - Clothes treating apparatus with minimized heat loss - Google Patents

Abstract

The present invention relates to a clothes processing apparatus which minimizes heat loss, and in accordance with an aspect of the present invention, A drum rotatably installed in the main body; An intake duct installed in the main body and communicating between the main body and the drum; And a heater installed inside the intake duct, wherein a heat radiation layer is formed on one or both of the inner wall surface of the drum and the inner wall surface of the intake duct, And the heat is radiated when heated by the hot air generated by the heat source.

Description

[0001] CLOTHES TREATING APPARATUS WITH MINIMIZED HEAT LOSS [0002]

The present invention relates to a clothes processing apparatus that minimizes heat loss, and more particularly, to a clothes processing apparatus having a function of drying clothing using hot air, such as a dryer or a washing machine having a drying function.

2. Description of the Related Art Generally, a garment treating apparatus having a drying function such as a washing machine or a dryer is used to put laundry in a state in which a washing process is completed and a dehydrating process is completed into a drum, and hot air is supplied into the drum to evaporate moisture of the laundry, It is a drying device.

For example, the dryer includes a drum that is rotatably installed in the main body and into which laundry is introduced, a driving motor that drives the drum, a blowing fan that blows air into the drum, And a heating means for heating the air introduced into the space. The heating means may utilize the high-temperature electric resistance heat generated by using the electric resistance or the combustion heat generated by burning the gas.

On the other hand, the air exiting the drum has the moisture of laundry in the drum, and becomes hot and humid air. At this time, the dryer can be classified according to the method of treating the high temperature and high humidity air. The air temperature and humidity are circulated without being discharged to the outside of the dryer, and the air is cooled to below the dew point temperature through the condenser, A condensing type (circulation type) dryer for condensing moisture, and an exhaust type dryer for discharging the high-temperature and high-humidity air passing through the drum directly to the outside.

In any type of dryer, the heating means is located at the bottom of the drum, and hot air heated by the heating means is supplied into the drum through a rear duct extending between the heating means and the rear surface of the drum. At this time, as the heating means, a combustion heater using fuel such as liquefied gas or an electric heater using electric resistance is used, which is disposed along the longitudinal direction of the intake duct.

The heat generated in the heater is used only to generate hot air and the remaining heat is not used in the clothes drying process and is discharged to the outside to cause heat loss. Nearly 50%.

The heat loss can be classified into heat loss due to exhaust air and heat loss generated in the process of moving the generated hot air into the drum. In the course of moving to the inside of the drum, Heat is transferred to the intake duct and the drum, resulting in heat loss.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a clothes processing apparatus which minimizes the loss of heat energy that can be generated in a process of transferring hot air generated by a heater to a drum, It is an assignment.

According to an aspect of the present invention, A drum rotatably installed in the main body; An intake duct installed in the main body and communicating between the main body and the drum; And a heater installed inside the intake duct, wherein a heat radiation layer is formed on one or both of the inner wall surface of the drum and the inner wall surface of the intake duct, And the heat is radiated when heated by the hot air generated by the heat source.

In the above aspect of the present invention, a heat radiation layer is formed on the surface of the drum or the intake duct, which absorbs part of the heat energy generated by the heater, so that the absorbed energy can be re-emitted, thereby minimizing the loss of heat energy . At this time, since the formed heat radiation layer can also function as a kind of heat insulating layer, a function of minimizing leakage of heat inside the drum or intake duct to the outside can be expected.

At this time, the heat radiation layer may be formed over the entire interior of the intake duct and the drum, or may be formed only in a part of the interior. Further, it may be formed either in the intake duct or in the drum, or in both of them.

Here, the intake duct includes a heater case surrounding the heater and disposed under the drum, and the heat radiation layer may be formed on an inner wall surface of the heater case.

Further, the intake duct may further include a rear duct communicating with the heater case and the drum, respectively, disposed on a rear surface of the drum, and the heat radiation layer may be formed on an inner wall surface of the rear duct. In addition, a heat radiation layer may be formed on both the rear duct and the heater case.

The heat radiation layer may be formed of a material having a lower heat transfer coefficient than the material of the intake duct or the drum. As a result, the heat energy leaking out of the drum or the intake duct can be minimized.

The heat radiation layer may be made of an insulating material. This makes it possible to enhance the insulation of the device and improve the stability.

In addition, the heat radiation layer may be formed of a material having corrosion resistance and heat resistance superior to that of the intake duct or the drum. As a result, the life of the intake duct and the drum can be improved.

Here, as the material satisfying the above-mentioned conditions, various kinds of materials may exist. For example, the heat radiation layer may be made of an inorganic ceramic material including silicon oxide.

In addition, the heat radiation layer may have a high reflectance color, for example, white. As a result, not only the absorption rate of heat energy can be lowered but also the effect of improving the aesthetics can be obtained.

According to aspects of the present invention having the above-described structure, it is possible to minimize the loss of heat energy generated during the process of generating hot air through the heater and supplying it to the inside of the drum, Thereby reducing the energy consumption required to operate the apparatus.

1 is a perspective view showing an example of a clothes processing apparatus according to the present invention.
2 is a cross-sectional view schematically showing the internal structure of the embodiment shown in Fig.
FIG. 3 is a photograph showing the heater case used in the embodiment shown in FIG. 1 and a conventional heater case.
FIG. 4 is a photograph showing a rear duct used in the embodiment shown in FIG. 1 and a conventional rear duct.
FIG. 5 is a photograph showing a drum used in the embodiment shown in FIG. 1 and a conventional drum.

Hereinafter, embodiments of a clothes dryer according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating an embodiment of a clothes processing apparatus according to the present invention. The embodiment is related to a dryer, but the present invention is not limited to a dryer. The present invention can be applied to any type of clothes processing apparatus that discharges the hot air to the outside.

Referring to FIG. 1, the dryer 100 includes a main body 102 constituting the outer shape of the main body 102, and a discharge port 104 are formed. The input port 104 is opened and closed by a door 106 and an operation panel 108 having various operation buttons for operating the dryer is positioned above the input port 104.

2 is a partial cutaway view schematically showing the internal structure of the dryer 100. As shown in FIG. Referring to FIG. 2, a drum 120 is rotatably installed in the body 102 to dry the object, and the drum 120 is supported by a supporter And is rotatably supported. The drum 120 is connected to a power transmission belt (not shown) and a driving motor provided at a lower portion of the dryer, and is rotationally driven by receiving a rotational force.

A heater case 130 is installed at a lower portion of the drum 120 and a rear duct 140 disposed at a rear of the heater case 130 in a vertical direction of the body 102. The heater case and the rear ducts 130 and 140 function as an air intake duct that is introduced from the outside and sucks outside air existing inside the main body 102 and supplies the outside air to the inside of the drum 120. At this time, a heater 150 is installed inside the heater case 130 to heat the low temperature outside air to be sucked to a high temperature required for drying laundry. The heater 150 may use an electric heater using a resistor or a combustion heater using a fuel such as a liquefied gas, and one or more heaters may be installed.

Here, the heater case and the rear ducts 130 and 140 are shown as two physically separated structures, but the present invention is not limited thereto, and both of the heater case and the rear ducts 140 and 140 may be integrally formed.

At this time, the inlet port of the heater case 130 is located inside the main body 102, and the outside air flows through the inlet port 110 formed at the lower portion of the inlet port of the heater case 130, Lt; / RTI > A plurality of the air intake openings 110 are formed in a slit shape, and outside air introduced from the outside can be directly introduced into the air intake openings 110. The outside air thus introduced is heated by the heater 150 and is introduced into the rear duct 140 as hot air at a high temperature (about 300 ° C) and then supplied to the drum.

The hot air thus supplied flows into the front duct 160 located at the lower side of the front surface of the drum 120 after the laundry contained in the drum is dried. The air introduced into the front duct 160 includes foreign matter such as lint or dust present on the surface of the laundry. A lint filter 162 for filtering the air is installed inside the front duct 160, So that foreign matter can be filtered through the lint filter 162.

A first exhaust duct 180 is connected to the front duct 160. The first exhaust duct 180 forms a part of an exhaust flow path for discharging hot air passing through the front duct 160 to the outside of the main body 102. Inside the first exhaust duct 180, A blowing fan 170 for sucking air in the drum 120 and blowing air to the outside of the dryer is installed.

The blowing fan 170 included in the embodiment is a full type blowing fan that exists on a duct through which the air is exhausted from the drum and sucks the air discharged from the drum toward the exhaust duct. However, depending on the configuration of the dryer, the air blowing fan may be positioned in the heater case 130 to which the hot air is supplied to the drum, and the heated air in the suction duct may be pushed into the drum.

The blowing fan 170 is driven by the above-described driving motor. In other words, a pulley for driving the power transmission belt is provided on one side of the driving motor, and the blowing fan is connected to the other side, so that both the blowing fan and the drum 120 are driven . Therefore, in the above embodiment, when the driving motor rotates, the drum and the blowing fan simultaneously rotate. A system that simultaneously drives a drum and a blower fan using one motor is called a 1-motor system. However, the present invention is not limited to the one-motor system. The drum driving motor for rotating the drum 120 and the fan motor for rotating the blowing fan 170 may be separate motors, The so-called two-motor system can be considered.

A second exhaust duct 190 is disposed at the rear end of the first exhaust duct 180 and a distal end of the second exhaust duct 190 communicates with the outside of the main body 102 to function as an exhaust port do. As a result, the exhaust passage is constituted by the first and second exhaust ducts and the connecting portion. Accordingly, the air sucked through the heater case 130 flows through the rear duct 140, the drum 120, the front duct 160, the first exhaust duct 180, and the second exhaust duct 190 sequentially To the outside of the main body.

3 is a photograph showing the heater case 130 and the conventional heater case. As shown in FIG. 3, a white heat radiation layer is formed on the surface of the heater case 130. The heat radiation layer is formed by applying an inorganic ceramic material containing silicon oxide and then baking at a temperature of 180 to 200 ° C for 20 to 30 minutes. Specifically, a binder such as silane such as RnSiX ₄ -n or an oligomer derived therefrom is used in an amount of 40 to 50 wt% and a binder of 20 to 40 wt% of powdery silicon oxide (SiO2) having a particle size of 0.2 to 1.0 mu m 34 to 27 wt% of a silicon mixture which is obtained by mixing 80 to 60 wt% of water and chemically reacting with the binder silane or an oligomer derived therefrom, and a mixture of 34 to 27 wt% of the silicon mixture to prevent cracking of the coating film, 10 to 19% by weight of a functional filler for improving physical and chemical properties, 1 to 2% by weight of a pigment powder for coloring, and 15 to 2% by weight of ceramic powder for emitting far-infrared rays and anions.

Such an inorganic ceramic material is generally the same kind as a coating layer formed on the surface of a cooking device or the like to prevent food and beverage from sticking to it, and an enamel material can be used.

In addition, the white pigment is used to increase the reflectance of the radiant energy transmitted from the heater or the like, thereby reducing the heat energy absorbed by the heater case. In addition, when the heat radiation layer is heated up to about 300 ° C which is the temperature of hot air, heat energy is radiated from the heat radiation layer, and the energy thus radiated is reused for heating the air passing through the heater case. And it plays a role of reducing energy consumption.

In addition, since the surface roughness is low and contaminants do not adhere well, the inner surface of the heater case can be maintained in a clean state even when used for a long period of time. In addition, corrosion resistance and heat resistance can be improved by using an aluminum alloy (Alloy 2024) . In addition, the heat conduction coefficient is 186k (W / mK) for the aluminum alloy, and the heat radiation layer is only 49k (W / mK), which is excellent in heat insulation performance.

Since the inorganic ceramic material is basically an insulating material, it is also possible to prevent short-circuiting inside the heater due to deflection of the heat rays.

The heat radiation layer is formed not only in the heater case but also inside the rear duct and the drum. FIG. 4 is a photograph showing the above-described rear duct 130 and a conventional rear duct, and FIG. 5 is a photograph showing the drum 120 and a conventional drum. As described above, the heat radiation layer improves the corrosion resistance, the heat insulation property, the stain resistance and the insulation property of the rear duct and the drum, thereby minimizing the loss of heat energy and improving the lifetime of each component.

In particular, unlike the heater case and the rear duct, the drum rotates at a speed of about 60 rpm during the drying process, so heat loss due to convection is large. However, due to the high heat- The amount of heat loss is greatly reduced. Specifically, the heat transfer coefficient due to the convection (hereinafter, referred to as "natural convection") in the fixed part is only one tenth of the convection (hereinafter, referred to as "forced convection") in the rotating drum. That is, the heat loss due to the convection in the case of forced convection is theoretically 10 times or more as compared with the case of the natural convection, but the heat loss as described above can be reduced to a minimum due to the presence of the heat radiation layer , Which leads to an increase in thermal efficiency.

Since the inside of the drum is directly exposed to the user in the process of putting in or taking out the clothes through the above-described inlet, the presence of the white heat radiation layer not only improves the aesthetics transmitted to the user, Impression is given. Also, due to the high stain resistance, it is possible to prevent discoloration of the inner wall surface of the drum due to a high temperature during the drying process or stain due to the detergent, thereby maintaining a clean state for a long period of time.

Claims (10)

main body;
A drum rotatably installed in the main body and containing an object to be dried therein;
An intake duct installed in the main body and communicating between the main body and the drum; And
And a heater installed inside the intake duct,
A heat radiation layer is formed on an inner wall surface of the drum, and when the heat radiation layer is heated to a predetermined temperature or more by hot air generated by the heater or the heater,
Wherein the heat radiation layer is made of an inorganic ceramic material containing silicon oxide. The method according to claim 1,
Wherein the intake duct includes a heater case surrounding the heater and disposed at a lower portion of the drum,
Wherein a heat radiation layer made of an inorganic ceramic material containing silicon oxide is formed on an inner wall surface of the heater case. 3. The method of claim 2,
The intake duct further includes a rear duct communicating with the heater case and the drum, respectively, and disposed on a rear surface of the drum,
Wherein a heat radiation layer made of an inorganic ceramic material including silicon oxide is formed on an inner wall surface of the rear duct. The method according to claim 1,
Wherein the heat radiation layer has a lower heat transfer coefficient than the material of the intake duct or the drum. The method according to claim 1,
Wherein the heat radiation layer is made of an insulating material. The method according to claim 1,
Wherein the heat radiation layer has corrosion resistance and heat resistance superior to the material of the intake duct or the drum. The method according to claim 1,
The inorganic ceramic material may be,
40 to 50 wt% binder acting as a binder;
34 to 27 wt% of a silicon mixture formed by mixing 80 to 60 wt% of water with 20 to 40 wt% of powdered silicon oxide (SiO ₂ );
10 to 19 wt% of a functional filler formed between the binder and the silicon mixture;
1 to 2 wt% of pigment powder; And
And 15 to 2 wt% of a ceramic powder which emits far infrared rays and emits negative ions. 8. The method of claim 7,
Wherein the binder is an oligomer derived from silane or the silane. 9. The method of claim 8,
Wherein the silicon mixture is chemically reacted with the silane or oligomer. 8. The method of claim 7,
Wherein said powder silicon oxide has a particle size of 0.2 to 0.1 mu m.

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