RU2419697C2 - Drying box unit and washing machine with such unit - Google Patents

Abstract

FIELD: textile, paper.

SUBSTANCE: drying box unit, comprising: a lower channel; a reflector, arranged on the inner periphery of the lower channel; a bracket for a heating device installed in the upper part of the reflector; a heating device installed on the bracket for the heating device in the lower channel, to generate heat; a fan assembly installed at the side of the lower channel, for air suction; and an upper channel connected to the upper part of the lower channel; a spacer element to locate the reflector at the distance from the lower channel, besides, the spacer device protrudes from the lower part of the lower channel or is arranged as concave, in order to protrude downwards from a part of the reflector.

EFFECT: development of a drying box unit, which is made of light material, capable to withstand high temperature, and a washing machine, comprising such a unit.

24 cl, 14 dwg

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The present invention relates to a drying box assembly and a washing machine having such a assembly.

Description of the prior art

Basically, a washing machine with a drying function is a household appliance that can wash and dry laundry.

Washing machines with a drying function are divided into a steam outlet type, in which air from the drum is discharged to the outside during the drying process, and a condensation type, in which air is not discharged from the drum, but circulated in the washing machine.

The condensation washing machine comprises a drying box located on the upper part of the tank and a heating device installed in the drying box. The heating device heats the air supplied to the drum to a high temperature. A condensation channel for connecting the drying box to the drum holding tank is installed to lower the temperature of the air leaving the drum. The air passing through the condensation channel is returned to the drying box. The air is heated to a high temperature and becomes dry in the drying box and is sent to the drum. This circulation process is repeated.

Meanwhile, when electric power is supplied to the heating device installed in the drying box, the heating device generates heat with a temperature of approximately 700 ° C, and thus, the air maintains a temperature of approximately 120 ° C.

Therefore, the drying box is usually made of metal capable of withstanding high temperatures. For example, a drying box is made of aluminum by injection molding.

However, when the drying box is made of aluminum during injection molding, the production cost rises and the total weight of the drum type washing machine also increases.

In addition, the housing on which the front and rear surfaces of the drying box rests must be rigid enough to withstand the load of the drying box. This is also a reason for increasing the cost of manufacturing a washing machine.

In addition, when the dryer box is made of aluminum by injection molding, the thickness of the dryer box increases, and thus, the total volume of the washing machine increases, or the internal volume of the dryer box decreases.

SUMMARY OF THE INVENTION

Therefore, the present invention relates to a drying box assembly and a washing machine comprising a drying box assembly which substantially eliminate one or more problems due to limitations and disadvantages of the prior art.

An object of the present invention is to provide a drying box assembly that is made of light material capable of withstanding high temperatures and a washing machine comprising such a drying box assembly.

Another objective of the present invention is to provide a drying box assembly, which may be inexpensive to manufacture and having increased internal volume, and a washing machine comprising a drying box assembly.

Additional advantages, objectives, and features of the present invention will be partially discussed in the following description and partially understood by those skilled in the art after studying the following, or may be studied by practicing the present invention. The objectives and other advantages of the present invention can be realized and achieved using the design specifically specified in the description and claims, as well as in the accompanying drawings.

To achieve these goals and other advantages, and also in accordance with the purpose of the present invention, as embodied and broadly described herein, a drying box assembly including a lower channel is described; an upper channel connected to the upper part of the lower channel; a reflector located on one of the inner periphery of the lower channel and the upper channel; a heating device installed in the lower channel to generate heat; and a fan assembly mounted on the lower duct side for suctioning air.

In another aspect of the present invention, a drying box assembly including a lower channel is described; an upper channel connected to the upper part of the lower channel to form an air channel; a reflector located on one of the inner periphery of the lower channel and the upper channel; a heating device for heating the air entering the air duct; a fan assembly located on the support portion of the fan for suctioning air; and a channel connector connected to one of the lower channel and the upper channel to direct the air sucked by the fan assembly into the drum.

In yet another aspect of the present invention, a drying box assembly is provided comprising a lower channel around which a sealing member is mounted and which is made of plastic or syndiotactic polystyrenes (SPS); an upper channel covering the upper part of the lower channel; a reflector made of metal and located on the inner periphery of the lower channel; and a heating device located in a space formed between the lower channel and the upper channel.

In yet another aspect of the present invention, a drying box assembly is described, including an upper channel and a lower channel, which are made of plastic or syndiotactic polystyrenes (SPS); a heating device located in a space formed between the upper channel and the lower channel; a reflector located between the part of the plastic or syndiotactic polystyrene of the lower channel and the heating device; and a spacer element for positioning the reflector at a distance from the plastic or syndiotactic polystyrene (SPS) part.

In yet another aspect of the present invention, a drying box assembly is described comprising a lower channel comprising a fan support portion located at a first end and a step portion formed at an inner periphery; an upper channel covering the lower channel to form an air channel; a reflector located between the lower channel and the upper channel and having a first end in contact with the stepped part; and a fan assembly mounted on the support portion of the fan.

In yet another aspect of the present invention, a washing machine is described, comprising: a drum into which laundry is loaded; drum holding tank; a drying box assembly located on the outside of the pipe for supplying hot air flow to the drum; and a condensation channel connected to the tank, the moist air leaving the tank passing along the condensation channel, in which the drying duct assembly includes an upper channel and a lower channel, which are made of plastic or syndiotactic polystyrenes; a heating device located in a space formed between the upper channel and the lower channel; a reflector located between a part of plastic or syndiotactic polystyrenes of the lower channel and a heating device, the reflector being made of metal; an expansion element for positioning the reflector at a distance from a part made of plastic or syndiotactic polystyrenes; and a fan assembly for suctioning outside air and directing intake air into the tank.

In accordance with the present invention, the weight of the drying box can be reduced.

Since the drying box assembly is made of heat-resistant plastic by injection molding, it is difficult to deform even at high temperature, and thus ignition is prevented.

In addition, since the total weight of the washing machine equipped with the dryer assembly is reduced, it is easier to deliver.

In addition, since the weight of the drying box is reduced, the load applied to the housing supporting the drying box is reduced. Therefore, the housing does not require high-strength material. Therefore, the range of material selection for the housing can be expanded.

You must understand that both the above brief description and the following detailed description of the present invention are illustrative and explanatory and are intended to provide an additional explanation of the present invention claimed in the claims.

Brief Description of the Drawings

The accompanying drawings, which are included to provide a further understanding of the present invention and form part of this application, illustrate an embodiment (s) of the present invention and together with the description serve to explain the principle of the present invention. In the drawings:

figure 1 is a perspective view of a washing machine that uses the node of the drying box in accordance with an embodiment of the present invention;

figure 2 is a perspective view of the node of the drying duct in accordance with an embodiment of the present invention;

figure 3 is a perspective view with a spatial separation of the elements of the node of the drying box of figure 2;

figure 4 is a perspective view of the lower channel node of the drying box of figure 2;

5 is a view in section along the line I-I 'in figure 4;

6 is an enlarged view of region A of FIG. 5;

7 is a sectional view of a spacer element of a reflector in accordance with another embodiment of the present invention;

Fig.8 is an enlarged view of region B of Fig.5;

Fig.9 is a view in section of a device for preventing the passage of pile in accordance with another embodiment of the present invention;

10 is a perspective view of a reflector in accordance with an embodiment of the present invention;

11 is a view in section along the line II-II 'in figure 2;

12 is an enlarged view of a region C of FIG. 11;

13 is a view illustrating a method for connecting a reflector and a lower channel in accordance with another embodiment of the present invention; and

FIG. 14 is an enlarged view of a region D of FIG. 11.

Detailed description of the present invention

Reference will be made in detail to preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as presented in the embodiments set forth herein; on the contrary, these embodiments are presented in such a way that this disclosure will be detailed and complete and will fully explain the idea of the present invention to those skilled in the art.

Figure 1 depicts a perspective view of a washing machine that uses the node of the drying box in accordance with an embodiment of the present invention.

A drum type washing machine will be described below.

As shown in FIG. 1, the washing machine 10 comprises a housing 11, a front cover 12 mounted on the front of the housing 11, a door 13 mounted pivotally on the front center portion of the front cover 12, a tank 15 installed in the housing 11 for placement water for washing, and a drum 14 installed in the tank 15. The laundry is loaded into the drum 14.

The washing machine 10 further comprises a detergent container 18 inserted into the housing 11 through the upper part of the front cover 12 for containing detergent, a softener and the like, a dispenser 17 for receiving the detergent container 18 and directing the flow of washing water, and a valve 16 for supplying water, mounted on the rear surface of the housing 11, for supplying water for washing. The valve 16 for supplying water and the dispenser 17 are connected using a hose for supplying water.

The washing machine 10 further comprises a drying box assembly 20 mounted on the top of the tub 15 for supplying hot air flow to the drum 14 during the drying process, and a control panel 19 mounted on the front surface of the front cover 12 and including an input device for entering a washing mode and a display for displaying the washing process.

The washing machine 10 further comprises a condensation channel installed in the housing 11. The condensation channel has a first end connected to the tub 15 and a second end connected to the dryer box assembly 20. A cooling water supply hose is connected to the upper part of the condensation channel so that the cooling water passes from the condensation channel.

The operation of the washing machine will be described below.

After opening the door 13 and loading the laundry into the drum 14, a detergent and / or softener are placed in the detergent container 18. Then, through the control panel 19, a washing mode is set and a button for controlling the machine is turned on. Then, electricity is supplied to the washing machine 10 to perform the washing, rinsing, spinning and spin drying processes in accordance with the entered washing mode.

Meanwhile, when the washing mode includes a hot drying process, electricity is supplied to the heating device installed in the drying box assembly after the spinning process in the centrifuge is completed. Then the drum 14 rotates at relatively low revolutions per minute to ensure multiple lifting and lowering of the laundry. In this case, the inlet fan installed in the node 20 of the drying duct is driven to suck in the air exiting to the front of the drum 14. Then, the air from the drum 14 passes to the node 20 of the drying duct along the condensation channel and heats up to high temperature and becomes dry. Dry air, heated to a high temperature, is sent to the drum 14 to absorb moisture from the laundry, so that the air becomes hot and humid. Hot and humid air leaves the drum 14 and moves up along the condensation channel.

Here, cooling water flows from the upper part of the condensation channel, and heat exchange occurs with the hot humid air, as a result of which the hot humid air cools as it passes through the condensation channel. The moisture contained in the moist air condenses and moves to the tank 15. The condensate sent to the tank 15 passes into the drainage pump installed in the lower part of the tank 15. In addition, the moist air rising along the condensation channel becomes dry and has a low temperature. . Air rising along the condensation channel passes into the drying box assembly 20 and is heated to a high temperature / dry state. This air then flows into the drum 14. The air circulation is repeated for a predetermined period of time.

Figure 2 depicts a perspective view of the node of the drying duct in accordance with an embodiment of the present invention, and Figure 3 depicts a perspective view with a spatial separation of the elements of the node of the drying duct in figure 2.

As shown in FIGS. 2 and 3, the drying duct assembly 20 includes a lower duct 21, an upper duct 22 located on the upper part of the lower duct 21, a duct sealing member 28 located on the upper edge of the lower duct 21, a fan assembly 24 mounted on the first the end of the lower channel 21, the channel connector 23 mounted on the second end of the lower channel 21, for connecting the node 20 of the drying duct with the tank 15, the heating device 25 installed in the node 20 of the drying duct, to generate heat with high temperature, reflector 27, install enny in the lower channel 21 and spaced apart from the lower channel 21, and a bracket 2 for a heating device for fixing the heating apparatus 25 so that the heating device 25 is located at a distance from the lower channel 21.

The fan assembly 24 includes a drying fan 241 for axially sucking in air and radially discharging air, a fan motor 244 located above the drying fan 241 to rotate the drying fan 241, an apparatus 242 for directing air to direct the air flow drawn in by the drying fan 241 , an electric motor housing 243 protruding upward from the upper surface of the air guiding device 242 and containing a fan motor 244, an electric mounting support 245 a motor located on the upper surface of the motor housing 243 and supporting the fan motor 244.

A sensor 29 for preventing overheating is installed in the Central side of the lower channel 21 to prevent overheating of the inner part of the node 20 of the drying box. A temperature sensor 30 is installed at the end of the lower channel 21, on which the channel connector 23 is mounted, for measuring the temperature of the air passing into the tank 15. That is, the temperature sensor 30 measures the temperature of the air supplied to the tank 15 to maintain the air temperature at 120 ° C. The channel sealing member 28 prevents high temperature air from leaking through the portion where the lower channel 21 is in contact with the upper channel 22.

In addition, the heating device 25 includes a contact pad 251 to which an electric wire is connected, a sealing element 252 of the heating device installed in a portion located at a distance from the contact pad 251 to prevent air leakage, and a heat generation element 253 passing from the contact platforms 251 and having a predetermined diameter and length. The contact pad 251 is bent in many areas. That is, the sealing element 252 of the heating device is mounted on the side surfaces of the reflector 27 and the lower channel 21 to prevent air leakage. The heat generation element 253 is a heating device in a casing with a heat conductor.

Meanwhile, the lower channel 21 and the channel connector 23 are in contact with high temperature air. Therefore, they are formed from a heat-resistant polymer during injection molding, so that they do not deform, do not bend.

Preferably, the lower channel 21 and the channel connector 23 may be made of the syndiotactic polystyrenes disclosed in Korean Patent Application No. 10-2003-0075942, filed by LG Chem. LTD. That is, syndiotactic polystyrenes are obtained by mixing styrene monomer and atactic polystyrenes with catalytic polymerization material. Syndiotactic polystyrenes are heat resistant and chemically resistant when taking advantage of the usual styrene polymer, such as low dielectric constant and good thermal fluidity.

In addition, the reflector 27 is fixed along the upper inner periphery of the lower channel 21. That is, the reflector 27 is made of a metal plate coated with aluminum. The reflector 27 is designed to effectively withstand heat with high temperature generated by the heating device 25. Therefore, the lower channel 21 is made of syndiotactic polystyrenes that can withstand high temperatures. Since the reflector is mounted on the upper part of the lower channel 21, deformation of the lower channel 21 due to exposure to high temperature heat generated by the heating device can be further prevented.

Here, the upper channel 22 is also made of syndiotactic polystyrenes, and the reflector is also fixed on the inner periphery of the upper channel 22. The device for directing air 242 is also made of syndiotactic polystyrenes. However, since the air guiding device 242 does not directly receive heat from the heating device 25, it can be made of plastic during injection molding.

Meanwhile, the reflector 27 is located at a distance from the upper surface of the lower channel 21. That is, a thin air layer is formed between the reflector 27 and the lower channel 21 to prevent direct transfer of heat transferred to the reflector 27 to the lower channel 21.

In addition, a stepped portion with a predetermined height is formed on the inner periphery of the lower channel 21, where the fan assembly 24 is located, to prevent the passage of foreign objects such as pile into the air layer. It will be described in more detail below.

Below will be described the purpose and operation of the node 20 of the drying duct.

When the hot drying process begins, electricity is supplied to the fan motor 244 to rotate the drying fan 241 and the heating device 25. Air is sucked into the drum 14 as a result of the rotation of the drying fan 241. The intake air flows along the air channel formed between the lower channel 21 and the upper channel 22 , for the implementation of heat exchange with the heating device 25. Air heated to a high temperature is supplied to the tank 15 through the channel connector 23. The air supplied to the tank 15, evaporating so the moisture contained in the laundry, thereby drying the laundry.

Figure 4 depicts a perspective view of the lower channel node of the drying duct in figure 2.

As shown in FIG. 4, the lower channel 21 has a longitudinal section formed in a U-shape.

That is, the lower channel 21 comprises at its end a supporting part 211a of a fan with a predetermined diameter. An air inlet opening 211 through which air passes is formed on the lower part of the fan supporting part 211a. The air channel is formed tangentially to the fan support part 211a. The air passage has a width increasing from the tangent portion to the fan support portion 211a. Therefore, the flow rate of air passing into the air channel during rotation of the fan support portion 211a decreases, and the time during which the air is exchanged with the heating device 25 increases.

Meanwhile, the lower channel 21 comprises a groove 217 on the side surface for mounting the sealing element of the heating device, into which the sealing element 252 of the heating device is inserted, and a groove 218 for installing the sensor to prevent overheating, into which the sensor 29 is inserted to prevent overheating. A channel sealing element 28 is located at the upper edge of the lower channel 21. The lower channel 21 contains at the second end an air outlet 212 through which high temperature air passes into the tank 15. The lower channel 21 further comprises a temperature sensor hole 219 on the side of the second end, in which is installed temperature sensor 30 (figure 5).

In addition, the lower channel 21 further comprises, on the upper edge side, a plurality of guide protrusions 210, so that the upper channel 22 can be connected in the correct position. The connecting protrusion 210a extends downward from the guide protrusion 210.

That is, the upper channel 22 is located on the upper surface of the lower channel 21, and the connecting element is inserted into the connecting protrusion 210a.

The supporting portion 213 of the bracket for the heating device protrudes from the lower part of the lower channel 21. That is, the bracket 26 for the heating device is fixed to the upper portion of the supporting portion 213 of the bracket for the heating device. The heating device 25 is supported by a bracket 26 for the heating device. The support portion 213 of the bracket for the heating device will be described below in more detail.

In addition, the support rib 216 is continuously or intermittently formed on the inner periphery of the lower channel 21, so that the reflector 27 can be located at a distance from the lower channel 21. The step portion 215 is formed at a portion located at a distance from the reflector 27. The support rib 216 and the step part 215 will be described below in more detail.

In accordance with the specified lower channel 211, the air passing through the air inlet 211 is heated to a high temperature by the heating device 25 and passes into the channel connector 23 through the air outlet 212. Then, the air is directed to the tank 15.

Fig. 5 is a sectional view taken along line I-I 'in Fig. 4, and Fig. 6 is an enlarged view of a region A of Fig. 5.

As shown in FIGS. 5 and 6, there is a reflector spacer for positioning the reflector 27 at a distance from the lower channel 21. That is, the support rib 216 protruding from the inner lower part of the lower channel 21 to a predetermined height serves as a reflector spacer.

That is, the supporting rib 216 can be continuously formed along the lateral and lower parts of the lower channel 21 or can be divided into many parts located at predetermined intervals. Alternatively, a plurality of protrusions, each of which has a predetermined height, can be formed on the inner periphery of the lower channel 21 as a spacer of the reflector. The support rib 216 or the support protrusions can be integrally formed with the lower channel 21 during injection molding.

7 is a sectional view of a spacer of a reflector in accordance with another embodiment of the present invention.

As shown in Fig.7, in order to position the reflector 27 at a distance from the lower channel 21, the reflector 27 contains one or more shaped parts 274.

That is, the reflector 27 is made of a thin metal plate by processing sheet metal, during which the upper surface of the reflector 27 is pressed down to a predetermined depth to form a concave surface. Then, the shaped part 274 is in linear contact with the lower channel 21, and thus, heat transfer from the reflector 27 to the lower channel 21 can be minimized.

Fig. 8 is an enlarged view of a region B of Fig. 5.

As shown in FIG. 8, since the reflector 27 is located at a predetermined distance from the lower channel 21, there is a need for a device to prevent the passage of the pile through the gap between the reflector 27 and the lower channel 21. Therefore, to prevent the formation of a gap at the end of the reflector 27, located next to the node 24 of the fan, the lower channel 21 is made with a stepped part 215.

That is, the lower channel 21 includes a step portion that extends downward from the upper surface, and the end of the reflector 27 contacts the step portion 215. According to such a connecting structure, the pile does not pass through the gap between the lower channel 21 and the reflector 27. In addition, since the lower the surface of the reflector 27 and the lower surface of the lower channel 21 are located in the same plane, the air drawn in by the inlet fan 241 passes along the inner side of the channel without encountering flow resistance.

Fig.9 depicts a view in section of a device for preventing the passage of pile in accordance with another embodiment of the present invention.

As shown in FIG. 9, a device is shown for preventing the passage of the pile through the gap between the reflector 27 and the lower channel 21 and preventing the end of the reflector 27 from rising.

That is, the elongated portion 215a is formed in the upper portion of the stepped portion 215 illustrated in FIG. The end of the reflector 27 is inserted into the groove formed in the lower portion of the elongated portion 215a. As a result, the raising or moving of the end of the reflector 27 can be eliminated with the help of the elongated portion 215a.

Here, since the elongated portion 215a extends in a direction in which air is sucked in by the drying fan 241, no flow resistance is created.

10 is a perspective view of a reflector in accordance with an embodiment of the present invention.

As shown in FIG. 10, a reflector 27 is formed by shearing and folding the sheet material to be processed. The outer periphery of the reflector 27 is coated with aluminum in order to minimize mold deformation at high temperature. Here, the upper channel 22 can be formed from the same material from which the reflector 27 is made. In this case, a heat-insulating element such as a reflector 27 is not required.

The supporting portion 273 of the bracket for the heating device is formed on the bottom of the reflector 27. The supporting portion 273 of the bracket for the heating device is formed by striking upward from the bottom.

The support portion 273 of the bracket for the heating device comprises a concave portion 273a on the upper surface, and the concave portion 273a includes a connecting hole 273b into which the connecting member is inserted. The lower end of the bracket 26 for the heating device is located in the concave part 273a, so as not to move. This will be described in more detail below.

The reflector 27 contains on the side surface a supporting part 271 of the sealing element of the heating device, into which the sealing element 252 of the heating device is installed. A hole 272 for the overheating sensor in which the sensor 29 for preventing overheating is installed is formed on the side surface of the reflector 27. The first end of the reflector 27 is in contact with the stepped part 215a of the lower channel 21, and the second end contains an air outlet corresponding to the air outlet formed on the end of the lower channel 21. The second end of the reflector 27 extends along the inner periphery of the lower channel 21 to the part connected to the channel connector 23. Therefore, the deformation The shape or melting of the lower channel 21 can be prevented during the passage of air, heated by the heating device 25, into the tank 15.

In contrast to the support groove 271 for the sealing element of the heating device, the sensor hole 272 is formed in a closed curved shape. This will be described in more detail below.

A sealing element is located on the outer periphery of the sensor 29 to prevent overheating. The sealing member may be formed of rubber. If the sealing element is damaged by heat, the sensor 29 may be closed to prevent overheating. In this case, heat detection may be inefficient. Therefore, in order to protect the sensor 29 to prevent overheating from the sealing member, a sensor hole 272 is formed to prevent overheating in a closed curved form, so that only the contact surface of the sensor 29 to prevent overheating can be exposed to heat.

FIG. 11 is a sectional view taken along line II-II ′ in FIG. 2, and FIG. 12 is an enlarged view of a region C of FIG. 11.

As shown in FIGS. 11 and 12, as described above, the drying box assembly 20 of the present invention comprises a lower channel 21, an upper channel 22 connected to the upper part of the lower channel 21, a reflector 27 mounted on the inner periphery of the lower channel 21, and an arm 26 for a heating device mounted on top of a reflector 27 to support the heating device.

The lower channel 21 contains in the center of the lower part the supporting part 213 of the bracket for the heating device, protruding upward. The concave portion 213a with a predetermined diameter and depth is formed on the upper surface of the support portion 213 of the bracket for the heating device. A connecting protrusion 213b is formed extending downward from the concave portion 213a. The connecting element 40 is inserted into the connecting protrusion 213b.

The heating device support portion 273 having the same shape as the heating device support portion 213 formed on the lower channel is also formed on the lower portion of the reflector 27. The concave portion 273a is formed on the upper surface of the heating device support portion 273 and a connecting hole 273b is formed in the center of the concave portion 273a. The connecting element 40 is inserted into the connecting hole 273b. The lower end 26 of the bracket 26 for the heating device is inserted into the concave portion 273a.

As described above, the element 253 for generating heat is connected to the upper part of the bracket 26 for the heating device. The lower part of the bracket 26 for the heating device is inserted into the concave part 273a. Therefore, even when the connecting member 40 is loosely tightened or removed from the connecting protrusion 213b, detachment of the bracket 26 for the heating device from the supporting portion 273 of the bracket for the heating device can be prevented. That is, the upper and lower ends of the bracket 26 for the heating device are fixed using the heating device 25 and the supporting portion 273 of the bracket for the heating device.

In addition, the connecting element 40 is intended not only for fixing the bracket 26 for the heating device on the lower channel 21 and the reflector 27, but also for fixing the reflector on the lower channel 21.

When molding the lower channel 21 from syndiotactic polystyrenes during injection molding, an element, such as a reflector 27, can be mounted on the inner periphery of the upper channel 22.

13 is a view illustrating a method for connecting a reflector and a lower channel in accordance with another embodiment of the present invention.

As shown in FIG. 13, a mounting protrusion protruding from the upper surface of the lower channel 21 is provided.

The fastening protrusion 210b may be integrally formed with the lower channel during injection molding. One or more mounting protrusions 210b may be formed. The length of the mounting protrusion 210b may be slightly larger than the length of the support rib 216. This will be described in more detail below.

The reflector 27 is mounted on the upper surface of the lower channel 21, on which the mounting protrusion 210b is formed. Here, the hole through which the fastening protrusion 210b passes is formed on the lower part of the reflector 27. When the reflector 27 is mounted on the support rib 216, the fastening protrusion 210b protrudes from the reflector 27. The protruding upper part of the fastening protrusion 210b is molten to fix the upper surface of the fastening protrusion 210b on the lower the surface of the reflector 27. In this process, the fastening protrusion 210b functions as a connecting element. When the protruding upper part of the fastening protrusion 210b melts, it spreads in the radial direction to completely seal the hole for the fastening protrusion formed on the reflector 27. Therefore, the pile does not pass through the hole and the gap between the reflector 27 and the lower channel 21.

FIG. 14 is an enlarged view of a region D of FIG. 11.

As shown in FIG. 14, a reflector 27 is formed along the inner periphery of the lower channel 21 in a shape identical to the inner periphery of the lower channel 21.

That is, the side of the reflector 27 is longer than the side of the lower channel 21 and protrudes above the upper surface of the lower channel 21.

As shown, the lateral upper end of the reflector 27 is higher than the lateral upper end of the lower channel 21 in order to direct the upper channel 22 to the correct position. Since the lateral end of the reflector 27 is elongated to have a sufficient length, damage to the sealing channel element 28 mounted on the upper surface of the lower channel 21 can be prevented by the action of high temperature air passing in the drying box assembly 20. The sealing channel element 28 is usually made of rubber, which is not heat resistant. Therefore, there is a need for a method for preventing damage to the sealing channel element 28 by high temperature air. This method is carried out by appropriately adjusting the length of the side of the reflector 27.

In addition, since the lateral end of the reflector 27 is longer than the lateral end of the lower channel 21, leakage of high temperature air from the drying unit assembly 20 can be prevented. That is, the prevention of air leakage can be carried out in a double way using the lateral end of the reflector 27 and the sealing channel element 28.

According to said drying box assembly, since the load of the drying box assembly is reduced while the heat resistance is increased, production costs are reduced and the safety problem can be solved.

Those skilled in the art will understand that various modifications and changes are possible in the present invention. Thus, it is understood that the present invention includes such modifications and changes of the present invention, provided that they are included in the scope of the attached claims and their equivalents.

Claims (24)

1. A drying box assembly comprising: a lower channel; a reflector located on the inner periphery of the lower channel; bracket for a heating device installed in the upper part of the reflector; a heating device mounted on a bracket for a heating device in the lower channel to generate heat; a fan assembly mounted on the lower duct side for suctioning air; and an upper channel connected to the upper part of the lower channel; a spacer element for positioning the reflector at a distance from the lower channel, the spacer device protruding from the lower part of the lower channel or made concave to protrude downward from the reflector part. 2. The node according to claim 1, additionally containing a channel connector connected to the other side of the lower channel. 3. The node according to claim 2, in which one of the lower channel, upper channel and channel connector is made of plastic or syndiotactic polystyrenes by injection molding. 4. The assembly according to claim 1, in which the reflector is formed of a metal sheet coated with aluminum. 5. The node according to claim 1, in which from the lower parts of the lower channel and the reflector protrude supporting sections supporting the bracket for the heating device. 6. The assembly according to claim 5, in which the concave portion is formed on the upper surface of the support portion, and the bracket for the heating device is mounted on the concave portion. 7. The assembly according to claim 5, further comprising a connecting protrusion extending downward from the support portion and the connecting element is inserted into the connecting protrusion after passing through the reflector. 8. The node according to claim 1, in which the side of the lower part of the lower channel is stepped to prevent the passage of foreign objects through the gap between the reflector and the lower channel. 9. The assembly according to claim 1, wherein in order to prevent leakage of air drawn in by the fan assembly, the side of the reflector has a height exceeding the height of the side of the lower channel. 10. The assembly according to claim 1, further comprising a connecting protrusion extending from an edge of the lower channel, the connecting element for attaching the upper channel being inserted into the connecting protrusion. 11. The node according to claim 1, in which the reflector closes the entire inner periphery of the lower channel, with the exception of the supporting part of the fan. 12. The node according to claim 1, in which the fan assembly includes a drying fan, a fan motor, an electric motor housing accommodating a fan motor, and an electric motor mounting support. 13. The node according to claim 1, additionally containing a sealing element that is installed around the lower channel. 14. The node according to claim 1, in which the reflector is located with a given gap from the inner periphery of the lower channel. 15. The assembly according to claim 1, wherein the support rib or support protrusion is formed on the lower part of the lower channel for the location of the reflector at a distance from the lower channel. 16. The node according to claim 1, in which the spacer element is a rib or protrusion protruding from the lower part of the lower channel. 17. The node according to claim 1, in which the spacer element is formed in the molding process. 18. The node according to claim 1, additionally containing a mounting protrusion protruding from the inner periphery of the lower channel and passing through the reflector. 19. The assembly of claim 18, wherein the upper end of the mounting protrusion protruding from the reflector is secured by a welding method. 20. The node according to claim 1, in which the upper surface of the reflector is located in the same plane as the stepped part, or in the area below the stepped part. 21. The assembly of claim 20, further comprising an elongated portion extending from the upper portion of the stepped portion to prevent the reflector from rising from the lower channel. 22. The node according to item 21, in which the elongated portion extends horizontally from the stepped portion, and the reflector is mounted on the lower portion of the elongated portion. 23. The node according to claim 1, additionally containing a sensor for detecting overheating of the inner part of the air channel; a sealing element located around the outer periphery of the sensor; a mounting groove formed on the side of the lower channel for mounting the sealing member; and a hole for the sensor formed on the side of the reflector, for access only to the measuring part of the sensor. 24. A washing machine comprising a drum into which laundry is loaded; a tank for placing a drum; a drying box assembly according to any one of claims 1 to 23, located on the outside of the pipe, for supplying hot air flow to the drum; and a condensation channel connected to the tank and made with the possibility of passing through it moist air exiting the tank.

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