KR100607267B1 - Condenser assembly of dryer - Google Patents

Abstract

The present invention relates to a dryer, and more particularly, to improve the indentation state of the condenser so that the indoor air in the low temperature state sucked by the circulating air in the high temperature and high humidity state passing through the condenser and / or the cooling fan is not leaked to the outside of the capacitor. The condenser assembly structure of the dryer for making.

The condenser structure of the dryer according to the present invention includes a condenser body; A capacitor outer part formed at a front part of the capacitor body and forming an edge of the front part of the capacitor; A condenser press member provided on both sides of the outer portion of the condenser to press the condenser; And a front sealing seat formed at a lower side of the capacitor outer portion and extending forwardly than the capacitor outer portion.

By the condenser structure of the dryer according to the present invention constituting the configuration as described above there is an effect that the user can easily detach the condenser.

Condenser, condenser press-in, sealing member

Description

Condenser assembly of dryer

1 is a cross-sectional view schematically showing a condensation drum dryer.

Figure 2 is a perspective view showing the base of the dryer in which the capacitor according to the spirit of the present invention is inserted.

3A is a front perspective view of a capacitor according to the spirit of the present invention.

3B is a rear perspective view of the capacitor.

3C is a side perspective view of the capacitor.

Figure 4a is an enlarged perspective view of the condenser indentation member in accordance with the teachings of the present invention.

4B is a perspective view illustrating a capacitor accommodating part in which the capacitor is accommodated.

4C is an enlarged perspective view showing a state in which a capacitor is press-fitted by the press-fitting member;

Figure 5 is an enlarged perspective view showing a capacitor handle formed on the front portion of the capacitor according to the spirit of the present invention.

Figure 6 is a perspective view showing a capacitor receiving portion is inserted capacitor according to the spirit of the present invention.

<Description of the symbols for the main parts of the drawings>

100: base 110: circulating air lowering portion 120: indoor air intake

130: cooling fan seating groove 140: motor heat dissipation groove 150: condensate storage unit

160: motor shaft insertion port 170: circulating air flow path 200: condenser

210: circulating air inlet 220: front sealing seat 230: circulating air outlet

240: rear sealing member 250: indoor air outlet 260: front sealing member

300: condenser indentation member 400: condenser detachable ring 500: guide rail

600: condenser accommodating part 610: accommodating part bottom 620: front part sealing surface

The present invention relates to a dryer, and more particularly, to improve the indentation state of the condenser so that the indoor air in the low temperature state sucked by the circulating air in the high temperature and high humidity state passing through the condenser and / or the cooling fan is not leaked to the outside of the capacitor. The condenser assembly structure of the dryer for making.

In general, a washing machine, a dryer or a combined washing machine provided with a drum device is a device using a rotational motion of a drum. That is, as the drum rotates, the laundry inside the drum also rotates, and the laundry rises and falls by the rotation.

For example, in the drum washing machine, a collision with the washing water occurs due to the rising and falling of the laundry, and the dirt on the laundry is removed by the collision.

In addition, the drum dryer is a device for blowing hot air generated by an electric heater or a gas combustion device into a drum to absorb moisture remaining in the object to be dried and to dry the object to be dried.

The present invention relates to a dryer for drying laundry by the rotation of the drum, hereinafter will be described taking a drum device used in the dryer as an example.

1 is a cross-sectional view schematically showing a condensing drum dryer.

Referring to Figure 1, the condensation-type drum dryer is configured to control the opening and closing of the cabinet 10, the cylindrical drum 12 formed inside the cabinet 10, and the drum 12 to form an appearance A door 13 and a belt 11 surrounding the outer circumferential surface of the drum 12 are included.

In addition, the motor shaft 21 is connected to the belt 11, the motor 17 is connected to the motor shaft to provide a rotational force, and the rotational force of the motor 17 is connected to the motor shaft 21 A cooling fan 16 that sucks and rotates the indoor air is included.

In addition, a drying fan 18 connected to the motor shaft 21 opposite the cooling fan 16 to circulate air inside the drum, and air sucked by the drying fan 18 may be connected to the drum ( As a passage to be moved to 12, the drying duct 19 is provided with a heat generating unit 20 therein.

In addition, a lint filter 14 formed below the opening through which the door 13 is inserted to filter foreign matter such as lint and the like contained in the wet air discharged from the drum, and air entering the lint filter 14 are condensers (not shown). It further includes a circulation duct 15 which is a passage to be moved to).

Hereinafter, the operation of the dryer will be described.

First, when power is applied to the dryer, the motor 17 rotates, and the heater 20 attached to the drying duct 19 is heated. In addition, the belt 11 connected to the motor shaft 21 rotates to rotate the drum 12. Then, as the drum 12 rotates, the object to be dried in the drum rotates along the inner wall of the drum and falls by its own weight when it reaches the uppermost side. Here, the object to be dried is lifted by a lift (not shown) attached to the inner wall of the drum.

On the other hand, the drying fan 18 connected to the motor shaft 21 is operated with the rotation of the motor 17, the circulating air passing through the lint filter 14 is sucked. The sucked air rises along the drying duct 19 and becomes a high temperature dry state through the heater. Then, the hot dry air absorbs the moisture present in the object to be dried while passing through the drum, resulting in a high temperature and high humidity.

In addition, the air of the high temperature and high humidity is again filtered by the lint filter 14 and then moved to a capacitor (not shown) along the circulation duct 15.

In addition, the cooling fan 16 connected to the motor shaft 21 is rotated to suck the indoor air outside the dryer. The sucked indoor air is then passed through a cooling fan 16 to the condenser.

Here, the hot and humid air moved to the capacitor along the circulation duct 15 and the indoor air sucked by the cooling fan 16 and moved to the capacitor pass through the capacitor. In addition, the hot and humid air and the indoor air are not mixed with each other by the shape of the capacitor, and only heat exchange occurs.

Therefore, the high temperature and high humidity air is changed to low temperature and high humidity air while losing heat to the indoor air while passing through the condenser. Then, as the temperature decreases, moisture contained in the air condenses and falls to the bottom of the condenser, and is moved to a sump (not shown) in which condensate is collected.

In addition, the water moved to the sump is moved to a condensate reservoir (not shown) located at the top of the dryer by a condensation pump.

On the other hand, the indoor air passing through the capacitor takes the heat of the high temperature and high humidity air and converts it into low temperature and high humidity air, and the temperature becomes high.

In the dryer having the above configuration, the condenser for condensing the internal air, which has become hot and humid while passing through the drum, must be kept in a completely closed state when assembled to the condenser receiving portion. If the sealed state is not maintained as described above, the condensed water generated while the drum internal air passes through the condenser does not move to the sump, and a problem of leaking to the outside of the dryer occurs.

In addition, when the capacitor is assembled in the dryer, the bottom surface of the capacitor is in contact with the bottom surface of the capacitor receiving portion, the friction force is generated, there is a disadvantage that it is not inserted smoothly during assembly.

In addition, there is a need for a handle structure to facilitate the user to hold and remove when the condenser is cleaned or replaced.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a condenser structure capable of maintaining a complete sealed state when the condenser is assembled to a dryer.

In addition, an object of the present invention is to provide a condenser having a handle structure that can be easily grasped or removed when the user inserts or removes the condenser into the dryer.

It is also an object of the present invention to provide a condenser structure with a structure for inserting the capacitor more smoothly and smoothly.

Condenser structure of the dryer according to the present invention for achieving the object as described above is a condenser body; A capacitor outer part formed at a front part of the capacitor body and forming an edge of the front part of the capacitor; A condenser press member provided on both sides of the outer portion of the condenser to press the condenser; And a front sealing seat formed at a lower side of the capacitor outer portion and extending forwardly than the capacitor outer portion.

By the above configuration, the condenser is completely sealed to the condenser accommodating part, and the user can easily attach and detach the condenser.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily made by adding, changing, or deleting other elements. I can suggest.

Figure 2 is a perspective view showing the base of the dryer in which the capacitor according to the spirit of the present invention is inserted.

Referring to FIG. 2, the base 100 of the dryer into which the condenser is inserted includes a circulating air lowering part 110 through which the internal air passing through the dryer drum and the door lint filter descends, and the circulating air lowering part 110. An inlet is formed at a lower side of the base, and a condenser 200 inserted into the rear side of the base and a circulating air flow path 170 formed at the rear side of the condenser 200 to move air passing through the condenser are included. .

In addition, the front right side of the base 100 is provided with an indoor air intake port 120 through which indoor air is sucked, and a cooling fan seating groove 130 for seating a cooling fan for sucking the indoor air.

In addition, the rear side of the cooling fan seating groove 130 is provided with a motor for providing a motive force for rotating the dryer drum, the motor heat dissipation groove 140 for cooling the heat generated by the motor is provided.

In addition, a condensate storage unit 150, in which condensate generated in the condenser 200 is collected, is provided at a central portion of the base 100.

Hereinafter, a brief description of the circulation of the fluid occurring inside the base 100.

As described above, the internal air passing through the inside of the drum is in a state of high temperature and high humidity and passes through the lint filter formed on the door side and the tub cover side, and passes through the condenser 200 via the circulating air lowering part 110. do. In addition, the indoor air sucked through the indoor air suction port 120 passes through the condenser 200 through a cooling fan.

Here, since the indoor air is lower in temperature than the circulating air, heat exchange occurs while passing through the capacitor.

In detail, in order to allow only heat exchange without the circulating air and the indoor air passing through the condenser 200, the circulating air flow path and the indoor air flow path are manufactured to intersect with each other inside the condenser 200.

On the other hand, the circulating air passing through the condenser 200 moves along the circulating air flow path 170 to a drying duct (not shown) provided on the rear wall of the dryer. Then, the indoor air passing through the capacitor 200 is discharged to the room again.

3A is a front perspective view of a capacitor according to the spirit of the present invention, FIG. 3B is a rear perspective view of the capacitor, and FIG. 3C is a side perspective view of the capacitor.

3A, 3B, and 3C, the capacitor 200 according to the present invention includes a capacitor body 270 and a capacitor outer portion formed at the front portion of the capacitor body 270 to form an edge of the capacitor front portion ( 211, the circulating air inlet 210 formed inside the condenser outer portion 211, the condenser detachable ring 400 formed at the center of the front surface of the condenser 200, and the condenser outer portion 211. Condenser indentation member 300 provided on both sides to press-fit the capacitor, and the front sealing seat 220 is formed extending from the lower side of the condenser outer portion 211 to extend longer than the condenser outer portion 211 ) Is included.

In detail, the rear surface of the condenser outer portion 211 includes a front sealing member 260 to maintain a complete sealed state when the capacitor is assembled.

In addition, the rear surface of the condenser 200 includes a rear sealing member 240 provided at an outer edge to maintain a closed state, and a circulating air outlet 230 through which the introduced circulating air is discharged.

In addition, the side of the condenser includes an indoor air inlet and outlet 250 through which the indoor air sucked by the suction force of the cooling fan flows in and out.

The circulating air inlet and outlet 210 and 230 and the indoor air outlet 250 are alternately layered alternately, so that only heat exchange occurs without direct contact.

In addition, by the front sealing member 260 provided on the front of the capacitor 200 and the rear sealing member 240 provided on the back of the capacitor, the indoor air and the circulation passing through the capacitor 200. Prevent air from leaking out of the condenser.

In this case, in order for the sealing members 240 and 260 to properly function, the condenser 200 needs to be press-fitted so as to be in close contact with the condenser seating portion (not shown).

4A is an enlarged perspective view of a condenser press-fitting member according to the spirit of the present invention, and FIG. 4B is a perspective view showing a condenser accommodating portion in which the condenser is accommodated, and FIG. .

4A, 4B, and 4C, the capacitor press-fitting member 300 according to the present invention is mounted on both sides of the capacitor outer portion 211 forming the capacitor front edge.

In detail, the press member 300 is inserted into the rotary shaft 350 in the center, the rotary shaft is coupled to the condenser outer portion 211.

More specifically, the rotating shaft 350 is preferably screwed to the outer portion 211 to form a screw shape.

In addition, the indentation member rotary lever is formed on the outer circumferential surface of the indentation member 300 protruding from the indentation protrusion 310 having a predetermined length and thickness, and is formed to be extended apart from the indentation protrusion 310 by a predetermined angle. 330 is included.

In detail, an upper part of the press member rotation lever 330 is formed to protrude upward from the press member member 340 for allowing the user to easily rotate the press member 300.

In addition, the capacitor accommodating part 600 into which the capacitor 200 is inserted and seated is a groove having the same shape as the capacitor. In addition, the capacitor accommodating part 600 includes a press projection protrusion insertion hole 111 for inserting a press projection formed in the press member on a side surface thereof.

In addition, a front sealing surface 620 is formed at an inlet of the accommodation part 600 to be in contact with the front sealing member 260 provided on the rear surface of the capacitor outer portion 211.

The indentation protrusion 310 formed on the outer circumferential surface of the indentation member has a predetermined thickness and includes an indentation inclined surface 320 formed by cutting an end portion by a predetermined angle.

In detail, the press-fitted inclined surface 320 is narrowed toward the end of the projection by the cutting as described above. In addition, the inclined surface 320 is formed to be inclined by a predetermined angle as rising from the bottom of the protrusion to the upper side.

Therefore, when the indentation protrusion 310 is inserted into the indentation protrusion insertion hole 111 provided on the side of the capacitor receiving portion 600, it can be inserted smoothly along the indentation inclined surface (320).

Referring to the press-fit process of the capacitor 200, first the capacitor 200 is pushed into the capacitor receiving portion 600.

When the capacitor 200 is completely inserted into the receiving part 600, the bottom surface of the indentation protrusion 310 is positioned in the indentation protrusion insertion hole 111. Here, when the pressing member handle 340 is rotated by hand, the pressing protrusion 310 is inserted into the pressing protrusion insertion hole 111 along the pressing inclined surface 320.

As a result, when the indentation protrusion 310 is completely inserted into the indentation protrusion insertion hole 111, the condenser 200 is to be indented by a length corresponding to the thickness of the indentation protrusion (310). Therefore, the sealing member provided in the front and rear portion of the capacitor 200 is strongly pressed into the sealing surface formed in the capacitor receiving portion, it is possible to maintain a complete sealed state.

5 is an enlarged perspective view illustrating a capacitor handle formed on the front portion of the capacitor according to the spirit of the present invention.

Referring to FIG. 5, a condenser attaching and detaching ring 400 having a diameter to which a user's finger can be inserted is provided at the center lower side of the front part of the condenser according to the present invention.

The user may periodically take out the condenser 200 and clean it. At this time, a device capable of holding the condenser is required.

Accordingly, a handle having a groove into which a user's finger can be inserted may be provided.

The capacitor detachable ring 400 is formed in a vertical direction on the front sealing seat 220 provided below the capacitor front part, and a groove having a predetermined diameter is formed in the center surface thereof.

Here, the position and shape of the condenser detachable ring 400 is not limited to the embodiment of the present invention, it turns out that the removable ring of various shapes provided in the position that is easy for the user to hold.

6 is a perspective view illustrating a capacitor accommodating part into which a capacitor according to the spirit of the present invention is inserted.

Referring to FIG. 6, a capacitor according to the present invention is fitted to a capacitor receiving part provided at one edge of a base of the dryer, and the capacitor receiving part 600 forms an inlet having the same shape as that of the condenser front part.

And, as described above, the inlet portion of the receiving portion 600 is formed with a front portion sealing surface 620 which is in surface contact with the front portion sealing member 260 of the capacitor, and the indentation protrusions on both side walls of the inlet portion. Indentation protrusion insertion hole 111 for inserting is formed.

In addition, the right side of the inside of the condenser accommodating part 600 is formed with an indoor air inlet 630 through which the indoor air sucked by the cooling fan is formed, and the back side of the accommodating part 600 passes the condensed air. Circulated air discharge port 640 is discharged.

In detail, the circulation air exiting to the circulation air outlet 640 is moved to a drying duct along the circulation air flow path 170.

Meanwhile, at least one guide rail 500 is formed on the bottom 610 of the capacitor accommodating part 600 and has a predetermined height and is elongated in the front-rear direction.

As described above, the condenser is inserted into the accommodating part 600 so that the frictional force acts less, so that the condenser is inserted smoother and softer.

Here, at least one support rib 510 for supporting the guide rail 500 may be formed on both side surfaces of the guide rail 500.

In addition, the height, thickness, and the number of the guide rails 500 provided on the bottom surface 610 of the accommodation part are not limited to the exemplary embodiment of the present invention.

By the condenser structure of the dryer according to the present invention constituting the configuration as described above there is an effect that the user can easily detach the condenser.

In addition, the capacitor is assembled while maintaining a completely closed state in the dryer, there is an effect that the condensate generated on the surface of the capacitor does not leak outside the dryer.

In addition, when the capacitor is inserted into the dryer, there is an effect that is inserted more smoothly and smoothly.

Claims (6)

Condenser body; A capacitor outer part formed at a front part of the capacitor body and forming an edge of the front part of the capacitor; A condenser press member provided on both sides of the outer portion of the condenser to press the condenser; And Condenser assembly structure of the dryer includes a front sealing seating portion extending from the lower side of the condenser outer portion extending forward than the condenser outer portion. The method of claim 1, The press-fit member is a condenser assembly structure of the dryer, characterized in that the rotation is inserted in the center, the rotation is possible. The method of claim 1, Condenser assembly of the dryer, characterized in that the indentation protrusion having a predetermined thickness and a predetermined length protrudes on the outer circumferential surface of the indentation member, the indentation projection is narrowed toward the end, and forms a indentation inclined surface inclined by a predetermined angle. rescue. The method of claim 1, The pressurizing member lever is formed on the outer circumferential surface of the press fitting member and protrudes by a predetermined length, and the press member member lever has a press fitting member handle on an upper side thereof. The method of claim 1, The indentation protrusion is inserted into the indentation projection insertion hole formed in the side wall of the capacitor receiving portion that accommodates the capacitor, condenser assembly structure of the dryer, characterized in that the condenser is pressed in the thickness of the indentation projection. The method of claim 1, The press-fit member is a condenser assembly structure of the dryer, characterized in that the plastic injection.

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