KR20140036684A - Laundry drier - Google Patents

Abstract

The present invention relates to a filter for removing lint generated by a laundry drier. According to an embodiment of the present invention specification, a laundry drier comprises: a cabinet for forming the outer appearance; a drum installed inside of the cabinet to be able to be rotated; a discharge duct for discharging the air inside of the drum; a fan for exhausting the air inside of the drum; a supplying duct for supplying air into the drum; a heater installed on the discharge duct for heating the air being supplied to the drum; and a filter unit installed on the discharge duct for collecting lint contained in the air being discharged. The filter unit may include a dual cyclone having a collision part where the lint is impacted. When the filter unit is used instead of a mesh filter or with a mesh filter, the weight removal efficiency can be increased up to 95 %; and the amount of fine lint collected on the discharge duct passage can be greatly reduced, which lengthens the cleaning period of the discharge duct.

Description

Dryer {Laundry drier}

The present invention relates to a dryer, and more particularly to an apparatus for removing fine lint generated in the dryer.

The dryer is a device that heats while forcibly blowing air through a fan and a heater installed on a flow path, and sends heated hot air to the drum to dry the laundry. The dryer processes air in the drum that absorbs moisture when the laundry is dried. It can be classified into condensation dryer and exhaust dryer according to the method.

The condensation dryer dries the object to be dried in the drum and then removes moisture by condensing it through a heat exchanger (condenser or heat pump module) without exhausting the humid air that is exhausted out of the dryer. It is sent back to the drum to recycle, and the exhaust dryer uses a method of heating the outside air to supply the drum and the humid air heat exchanged with the drying object directly to the outside of the dryer.

In the drying process, a large amount of fine lint is generated and accumulated in a fan, a duct, a heat exchanger, and the like, and a filter is disposed on a flow path of air discharged from the drum to filter the lint, as shown in FIG. The opening may be formed in the drying container, the filter may be seated under the opening, and an outlet through which the air exiting through the filter is discharged may be formed.

It is important to remove lint effectively, because a large amount of lint on the filter will not ensure a smooth air flow, which will reduce drying efficiency, increase drying time, increase internal temperatures excessively, cause malfunctions by static electricity, and even cause fire. .

To ensure the drying performance and stability of the dryer, the user sometimes has to take the filter out of the dryer and remove the lint from the filter, which is not cumbersome and can cause dust to blow around when cleaning the filter.

The present invention was made in view of the above situation, and an object of the present invention is to provide an apparatus for significantly reducing the amount of lint accumulated in the discharge duct flow path.

Dryer according to an embodiment of the present invention for achieving the above object, the cabinet forming the appearance; A drum rotatably installed in the cabinet; A discharge duct for discharging air in the drum; A blowing fan for exhausting air inside the drum; A supply duct for supplying air into the drum; A heater installed on the supply duct to heat air supplied into the drum; And a filter unit for collecting the lint included in the air discharged on the discharge duct, the filter unit including a dual cyclone including a collision part in which the lint included in the air discharged through the discharge duct collides. Characterized in that.

In an embodiment, the dual cyclone may include a cylindrical part having a predetermined diameter and allowing air to rotate along an inner surface thereof, and an inlet part formed in a tangential direction of the cylindrical part to allow air discharged from the drum to enter; And a first cyclone and a second cyclone formed along a central axis of the cylinder to include an outlet for allowing air entering the inlet to exit, wherein the first cyclone and the second cyclone may share the inlet. .

In one embodiment, each of the first cyclone and the second cyclone may be formed in the tangential direction of the cylindrical portion and may include a collecting portion protruding in a direction opposite to the direction of the air entering the inlet.

In one embodiment, the impingement may be formed where the dual cyclone extends from the inlet.

In one embodiment, the collision portion may be formed in a plane contacting the cylindrical portion of the first cyclone and the cylindrical portion of the second cyclone at the same time.

In one embodiment, the impingement portion may be composed of two surfaces protruding in a wedge shape toward the inlet portion in a plane perpendicular to the direction in which air is introduced from the inlet portion.

In one embodiment, the impingements share a straight line, the two faces being equal in distance from the center of the two cylinders, spaced apart by a first length toward the inlet in a plane that is in contact with the cylindrical portions of the two cyclones simultaneously, Each of the two surfaces may include any one of two straight lines that are spaced apart by a second length from a straight line having the same distance from the center of the two cylindrical portions among the straight lines lying in the plane.

In one embodiment, the first length and the second length may be determined in consideration of the shear stress to be applied to the lint growing in the impact portion.

In one embodiment, the two faces may be planar or part of a cylindrical column with a predetermined radius of curvature.

In one embodiment, the lower end of the inlet may be formed higher than the lower end of the outlet.

In one embodiment, the surface formed by the outer peripheral surface of the collecting portion and the cylindrical portion is opened by a third length at the lower end of the cyclone to form a hole, the lint flowing through the hole inside the cylindrical portion through the collecting portion Can flow in.

In one embodiment, the third length may be less than the length between the bottom of the cyclone and the bottom of the impact portion.

In one embodiment, the width of the inlet may be less than the distance between the centers of the two cylinders.

In one embodiment, the distance between the distal end of the inlet and the impingement may be less than or equal to the radius of the cylinder.

In one embodiment, the outer circumferential surface portion between the end of the inflow portion and the impact portion in the cylindrical portion is formed with an arc column only at the bottom and the arc column is not formed at the upper side, the top of the formed arc column is the same as the bottom of the inlet It may be formed at a high or low height.

Thus, dual cyclones with impingement plates can be used as lint removal devices instead of or in conjunction with mesh filters to improve weight removal efficiency by 95%.

In addition, the dual cyclone with impingement plate does not increase the drying time since there is no flow obstruction before the dust container is full.

In addition, since the user only needs to empty the cyclone dust container, the cleaning method becomes simple, and the cleaning cycle becomes very long.

In addition, since the amount of fine lint accumulated in the discharge duct flow path is significantly reduced, the cleaning cycle of the discharge duct can be taken very long.

1 shows a dryer equipped with a filter for filtering lint,
2 and 3 show a cross-sectional view and a plan view of the dryer, respectively.
4 illustrates a cross section in three directions of a filter unit according to an embodiment of the present invention;
5 is a cross-sectional view taken along the line AA ′ and BB ′ of FIG. 4;
Figure 6 shows a filter unit according to another embodiment of the present invention,
7 conceptually illustrates a front view and a plan view of a dryer having a filter unit according to the present invention.

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

As described in the prior art, the dryer is divided into an exhaust type dryer and a condensation dryer according to a method of treating air in the drum. Hereinafter, the condensation dryer is used as an embodiment of the present invention for convenience of description. With reference to the accompanying drawings will be described in detail a dryer according to an embodiment of the present invention.

As shown in Figure 1 and 2, the dryer 100 according to an embodiment of the present invention, the cabinet 110 to form a large appearance, rotatably installed inside the cabinet 110 to be dried And a drum 120 for receiving. In addition, the dryer 100 is connected to the rear of the cabinet duct 110 and the discharge duct 130 for discharging air containing a lot of moisture by heat exchange with the drying object in the drum 120 to the drum 120 It further comprises a supply duct 135 for supplying hot air.

In addition, the dryer 100 for treating the air inside the drum 120 in a condensation type may further include a condenser 140 for drying the object to be dried and dehumidifying the humidified air. The condenser may fall out.

A door 111 that can be opened and closed is mounted on the cabinet 110, and corresponds to the opening 112 formed in front of the drum 120, through which a user can put a dry object into and out of the drum 120. The rear of the dryer 100 may be covered by a rear cover 113, and a plurality of suction holes 114 may be formed in the rear cover 113 to allow external air to flow therein. A control panel (not shown) for controlling the operation of the dryer 100 and providing an interface with a user may be provided at the upper rear or front upper end of the dryer 100.

The front supporter 115 and the rear supporter 116 are installed between the cabinet 110, the drum 120, and the cabinet 110, respectively, and the front supporter 115 and the rear supporter 116 are each the drum ( The front and rear of the 120 to support the drum 120 is rotatable, and a sealing member (not shown) to prevent leakage between the front supporter 115 and the rear supporter 116 and the drum 120 to be installed. Can be. A plurality of through holes 117 are formed in the rear supporter 116 to allow hot air supplied through the supply duct 135 to enter the drum 120.

In the front supporter 115 and the rear supporter 116, a roller 118 may be mounted at a position corresponding to an upper side or a lower side of the front and rear of the drum 120 to support the drum 120 in a rotatable manner. have.

The inner space of the drum 120 functions as a drying chamber in which drying proceeds, and a lift 121 is installed inside the drum 120 to lift and drop the drying object to invert the drying object to increase the drying efficiency. Can be.

The motor 125 for rotating the drum 120 is mounted below the dryer 100, and the motor 125 is coupled to the pulley 126 to rotate the pulley 126 and is connected to the belt 127. Rotate the drum 120 through). In FIG. 2, an indirect driving method of rotating the drum 120 by using the motor 125, the pulley 126, and the belt 127 is illustrated and described for convenience, but the present invention is not limited thereto. The motor is connected to the rear of the can be applied to the direct drive method (Direct Drive Type) to directly rotate the drum 120.

A discharge port 131 is formed below the front supporter 115 to transfer air of the drum 120 to the discharge duct 130, and the discharge duct 130 may be disposed within the drum 120. Blowing fan 132 for exhausting air is installed, in the case of the condensation type dryer in which the discharge duct 130 and the supply duct 135 is connected to each other, the blower fan 132 is used for air in the drum 20 The exhaust duct 130, the condenser 140, and the supply duct 135 may be forced to the inside of the drum 20 again. When the internal air is circulated, such as a condensation type dryer, the blower fan 132 may be mounted in the supply duct 135 because it may be disposed at any position on the circulation passage.

The blowing fan 132 is driven by the motor 125, the motor 125 has two or more rotary shafts, one rotary shaft is connected to the blowing fan 132 to drive the blowing fan 132 The other rotation shaft may be connected to the pulley 126 to rotate the drum 120 through the pulley 126 and the belt 127.

The supply duct 135 may be provided with a heater 136 for heating the air or the outside air circulated to supply the hot air to the drum (120). The heater 136 heats the introduced dry air when the humid air circulated by the blower fan 132 is introduced into the supply duct 135 after being dehumidified through the condenser 140. The dried air is heated by the heater 136 and supplied again to the drum 120 through the supply duct 135. In this case, the heater 136 may be installed in the inlet or supply duct 135 into which air is introduced into the supply duct 135 so that heated air may be supplied into the drum 120 through the supply duct 135. have.

The condenser 140 is installed between the discharge duct 130 and the supply duct 135 to dehumidify the humid air exhausted through the discharge duct 130 to be supplied to the supply duct 135, the condenser ( One side of the 140 may be provided with a cooling fan 141 for cooling the condenser 140, the cooling fan 141 may be driven by the motor 125. The condensate generated by the condenser 140 may be drained out of the cabinet 110 by the drain pump assembly 143.

The condenser 140 may use both an air-cooled or water-cooled condenser, and in the case of using an air-cooled condenser, condensation of moisture through heat exchange by supplying outside air, which is relatively cooler than air, after drying, is supplied to the condenser 140. In the case of using a water-cooled condenser, moisture is condensed through heat exchange by supplying a refrigerant or cooling water to the condenser 140.

FIG. 3 is a view illustrating an air-cooled condenser. In order to condense the humid air discharged from the drum, cold air must be supplied from the outside of the cabinet 110 so that the dryer 100 receives an external air supply duct 144 for supplying external air. It may be provided. One side of the outside air supply duct 144 may be formed at one portion of the cabinet 110 to be connected to the outside, and the other side thereof may be connected to the condenser 140.

On the other hand, the connection portion between the outlet 131 and the discharge duct 130 may be provided with a filter unit 150 according to the present invention for filtering the air exhausted from the drum 120, as shown in FIG. A dual cyclone filter according to the invention is shown.

The filter unit 150 according to the present invention is characterized in that the two cyclones share with each other a collision part such that the air discharged from the drum collides with the dust contained in the air, and the particles are gradually enlarged and separated downward.

The filter unit 150 according to the present invention includes a first cyclone, an inlet 151, which is composed of an inlet 151, a cylinder 153 ₁ , an outlet 154 ₁ , and a collector 155 ₁ . the cylindrical portion (153 _2), outlet (154 ₂₎ and a collecting unit comprising: a second cyclone and a collision unit (152) consisting of (155 _2), the first cyclone and the second cyclone is the inlet 151 and the collision unit 152 may be shared with each other.

The inlet 151 is connected to an outlet 131 formed below the front supporter 115 to allow air from the drum 120 to flow therebetween, and between two cylindrical portions 153 ₁ and 153 ₂ . It may be located and in contact with the two cylindrical portion (153 ₁ , 153 ₂ ) at the same time.

The impingement part 152 is to allow the air introduced through the inlet part 151 to hit the lint included in the air, and to place the inlet part 151 where it extends from the inlet part 151. It is formed in a plane perpendicular to the flow of air coming through, and is formed to be in contact with the outside of the two cylindrical portions (153 ₁ , 153 ₂ ) at the same time.

The cylindrical portion 153 may provide a space in which the air divided into the two hits the collision portion 152 may rotate. The cylindrical portion 153 has a predetermined diameter so that the introduced air may rotate along the inner wall and the outer portion of the cylindrical portion 153 may rotate. In contact with the inlet 151 and the impact unit 152.

The outlet portion 154 is a passage through which the air descending while rotating in the cylindrical portion 153 exits, and may be formed in a pipe shape along an axial direction on a central axis of the cylindrical portion 153.

The collecting part 155 is a place where the dust that has collided with the colliding part 152 to accumulate and descends is formed in a tangential direction of the cylindrical part 153 and air enters from the inlet part 151. It protrudes in the opposite direction to accommodate larger dust. The collection unit 155 is preferably manufactured in a form that can be separated from the filter unit 150 and reattached so as to easily remove dust accumulated therein.

When the blowing fan 132 is driven while a drying object is accommodated in the drum 120, the air inside the drum 120 is discharged through an outlet 131 formed below the front supporter 115. Through the inlet 151 and hit the impact portion 152, lint in the air is deposited on the impact portion 152, the light air separated foreign matter is bounced by the impact portion 152 to the cylinder After turning down while turning along the inner circumferential surface of the part 153, the pressure is generated by the blowing fan 132 and flows out through the outlet 154 to the discharge duct 130.

The dust such as lint that is entangled with each other by colliding with the colliding portion 152 becomes larger than a predetermined size and becomes heavier than a predetermined size, so that the dust enters into the cylindrical portion 153, away from the colliding portion 152, and the cylindrical portion 153. In accordance with the flow of air generated in the inside is rotated downwards, due to its weight is accumulated in the collecting unit 155 by the rotational inertia without flowing out through the outlet 154.

It is advantageous to reduce the differential pressure by increasing the radius of the cylindrical portion 152 (5 in FIG. 4) to reduce the dust collection efficiency. Of the lint contained in the air entering through the inlet 151 having a predetermined width (2 in FIG. 4), the small lint which is not filtered by the rotational movement in the cyclone is the collision surface of the collision part 152 (FIG. 4). 1) (P in FIG. 4), grown to a dust-collectable size by rotation of the cyclone, and then separated from the impact surface by the shear stress effect due to flow. The lint having large particles separated from the collision surface is rotated down along the inner circumferential surface of the cylindrical portion 152, so that the outer circumferential surface portion of the cylindrical portion 152 where the cylindrical portion 152 and the collecting portion 155 meet (viewed in plan view). Is collected in the collecting portion 155 of the cyclone through a dust collecting opening 156 formed under a portion of a circle of a cylindrical portion (A ₂ in FIG. 4) (represented by P ′ in FIGS. 4 and 5). . The clean air from which lint is removed is rotated through the cylindrical portion 153 and is discharged through the outlet portion 154.

The lower end of the outlet portion 154 (the length descending from the upper end of the inlet portion 151, 8 in FIG. 4) is greater than the height of the inlet portion 151 (the length between the upper and lower ends, 7 in FIG. 4). Increasing the dust collecting efficiency by preventing the air introduced through the inlet 151 does not immediately exit the outlet 154 without rotating.

The width (2 in FIG. 4) of the inflow portion 151 is two cylindrical portions 153 ₁ , 153 so that the air flowing from the drum 120 may enter and rotate in the cylindrical portion 153 according to the flow flow. ₂ ) should be less than the distance between centers (1 in FIG. 4).

In addition, the end of the inlet portion 151 should extend close to the collision portion 152 so that the air flowing from the drum 120 enters and rotates the cylindrical portion 153 according to the flow flow. The distance between the distal end of the inlet 151 and the impact surface of the impact 152 (FIG. 4 to 10) should be equal to or smaller than the radius of the cylindrical portion 154 (5 to FIG. 4).

In the cylindrical portion 153 and the distal end of the inlet 151 so that the air introduced from the inlet 151 impinges on the collision part 152 and enters into the cylindrical part 153. A portion of the outer circumferential surface between the planes of the collision portion 152 (expressed as A ₁ in FIG. 4 as part of the arc of the cylindrical portion in plan view) (exactly an arc column consisting of the arc A ₁ as the outer circumferential portion of the cylindrical portion) Some sides of the column are formed and the top is not formed. The height at which the surface is not formed in the arc column corresponding to arc A ₁ may be equal to or greater than the height (7 in FIG. 4) of the inlet 151.

The upper end of the dust collecting opening 156 formed in the arc pillar made of arc A ₂ , the outer circumferential surface portion of the cylindrical portion 152 where the cylindrical portion 152 and the collecting portion 155 meet (the lower end of the cyclone in FIGS. 4 and 5). The height from 9 is to be formed below the bottom of the outlet 154 (height is represented by 8 from the top of the cyclone in Figure 4).

6 illustrates a dual cyclone filter unit according to another embodiment of the present invention.

If the shear stress due to flow is weak, the lint collected on the impact surface of the impact portion 152 may not be separated from the impact surface. In the embodiment of FIG. 6, the collision part 152 is not formed in a single plane perpendicular to the direction in which air flows from the inflow part 151, and the collision part 152 is formed in the inflow part 151. Protruding symmetrically toward the inlet 151 in a plane perpendicular to the direction in which air is introduced may be formed in a wedge shape consisting of two surfaces.

More specifically expressed, the two cylinders in the inlet portion 151 perpendicular to the direction in which air flows, and the two cylindrical portions (153 _1, 153 _2), a first plane (S _P) in contact at the same time the part (153 _1, 153 ₂₎ a first distance (D ₁₎ a plan view of the first straight line (Fig. 6 projecting by the distance from the center toward the inlet 151 from the same 0th line (represented by point L ₀ in the plan view of FIG. 6) of the Is represented by the point L ₁ ) and two second straight lines separated by the second distance D ₂ from the zeroth line L ₀ on the first plane P ₁ to the point L ₂ in the plan view of FIG. 6. The impingement portion 152 may be formed by two planes (represented by lines S ₁ and S ₂ in the plan view of FIG. 6).

In other words, the two surfaces are two cylindrical portions (153 _1, 153 ₂₎ are of the same distance from the center of the two cylinder part section the inlet at (153 _1, 153 ₂₎ the first plane (P ₁₎ in contact at the same time The two cylindrical portions ( ₁ ) share a first straight line (L ₁ ), spaced apart by a first length (D ₁ ) toward 151, each of the two faces being on a first plane (P ₁ ). 153 ₁ , 153 ₂ and one of two straight lines L ₂ spaced apart by a second length from a zero straight line L ₀ having the same distance.

The two surfaces S ₁ and S ₂ forming the impingement 152 may be flat or part of a cylindrical column having a radius of curvature, in which case the radius of curvature is infinite.

The lint contained in the air from the drum 120 is accumulated on the first straight line L ₁ and is subjected to a greater shear stress than the impact portion 152 of FIG. 4. 6, the protrusion of the collision part 152 is controlled so that the lint grown to a desired size is separated by adjusting the shear stress applied to the lint that is collected and grown near L ₁ , which is a protruding portion of the collision part 152. You can change the shape, that is, one or more of the radii of curvature of D ₁ , D ₂ , S ₁ and S ₂ .

7 is a front view and a plan view showing a position of the filter unit in the dryer according to the present invention. In order to prevent lint from accumulating on the blower fan 132, the filter unit 150 according to the present invention may be disposed in front of the blower fan 132 and blower fan by the size of the filter unit 150 compared to a conventional dryer. 132 and the motor 125 may be moved backwards.

The dual cyclone type filter unit according to the present invention may be used in both an exhaust type dryer, a condensation type dryer and a combined washing machine.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. Addition or the like.

100: dryer 110: cabinet
111: door 112: opening
113: rear cover 114: suction hole
115: front supporter 116: rear supporter
117: through hole 118: roller
120: drum 121: lifter
125: motor 126: pulley
127: belt 130: discharge duct
131: outlet 132: blowing fan
135: supply duct 136: heater
140: condenser 141: cooling fan
142: drain pump assembly 143: air supply duct
150: filter portion 151: inlet portion
152: collision portion 153: cylindrical portion
154: outlet 155: collector
156: dust collecting opening

Claims (15)

A cabinet forming an appearance;
A drum rotatably installed in the cabinet;
A discharge duct for discharging air in the drum;
A blowing fan for exhausting air inside the drum;
A supply duct for supplying air into the drum;
A heater installed on the supply duct to heat air supplied into the drum; And
It is configured to include a filter unit for collecting the lint contained in the air discharged is installed on the discharge duct,
And the filter unit comprises a dual cyclone including a collision part in which a lint included in air discharged through the discharge duct collides. The method of claim 1,
The dual cyclone may include a cylindrical part having a predetermined diameter and allowing air to rotate along an inner surface thereof, and an inlet part formed in a tangential direction of the cylindrical part to allow air discharged from the drum to enter; And a first cyclone and a second cyclone formed along a central axis of the cylinder to include an outlet for allowing air entering the inlet to exit, wherein the first cyclone and the second cyclone share the inlet. Dryer. 3. The method of claim 2,
And the first cyclone and the second cyclone are respectively formed in a tangential direction of the cylindrical portion and include a collecting portion protruding in a direction opposite to a direction in which air enters from the inlet portion. 4. The method according to claim 2 or 3,
The dual cyclone dryer is characterized in that the impact portion is formed where it extends from the inlet. 5. The method of claim 4,
And the collision part is formed in a plane contacting the cylindrical part of the first cyclone and the cylindrical part of the second cyclone at the same time. 5. The method of claim 4,
The impact unit is characterized in that the dryer consists of two surfaces protruding in a wedge shape toward the inlet in a plane perpendicular to the direction in which air is introduced from the inlet. The method according to claim 6,
The impingements share a straight line, the two faces being equal in distance from the center of the two cylindrical parts, spaced apart by a first length toward the inlet in a plane that is in contact with the cylindrical parts of the two cyclones simultaneously, each of the two faces Is one of two straight lines which are spaced apart by a second length from a straight line having a distance from the center of the two cylindrical portions among the straight lines lying in the plane. 8. The method of claim 7,
And the first length and the second length are determined in consideration of the shear stress to be applied to the lint growing on the impacted portion. The method according to claim 6,
And said two sides are planar or part of a cylindrical column having a predetermined radius of curvature. 3. The method of claim 2,
And a lower end of the inlet is formed higher than a lower end of the outlet. The method of claim 3, wherein
The surface formed by the outer circumferential surface of the collecting portion and the cylindrical portion is opened by a third length at the lower end of the cyclone to form a hole, through which the lint flowing in the cylindrical portion flows into the collecting portion. Dryer. 12. The method of claim 11,
And the third length is less than a length between the bottom of the cyclone and the bottom of the impingement. 3. The method of claim 2,
And the width of the inlet is smaller than the distance between the centers of the two cylinders. 3. The method of claim 2,
And the distance between the distal end of the inlet and the impingement is less than or equal to the radius of the cylinder. 3. The method of claim 2,
An outer circumferential surface portion between the end of the inflow portion and the impact portion in the cylindrical portion is formed with an arc column only at the bottom and the arc column is not formed at the upper side, the upper end of the formed arc column is at the same height or lower than the lower end of the inlet portion Dryer, characterized in that formed.

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