KR101411125B1 - Dust separating apparatus of vacuum cleaner - Google Patents

Abstract

The present embodiment relates to a dust separator for a vacuum cleaner.

The dust separating apparatus of the vacuum cleaner according to the present embodiment includes: a dust separating unit in which a plurality of suction portions are formed; A flow guide portion in which a plurality of branch flow paths communicating with the respective suction portions are formed; A partition formed in the flow guide portion to form a separation chamber for separating dust from air sucked into the flow guide portion; A suction guide pipe for guiding air containing dust to the flow guide portion to be moved; And a dust storage portion in which dust separated from the dust separation unit is stored.

Dust, separation

Description

TECHNICAL FIELD [0001] The present invention relates to a dust separating apparatus for a vacuum cleaner,

The present embodiment relates to a dust separator for a vacuum cleaner.

Generally, a vacuum cleaner sucks air containing dust by using a suction force generated by a suction motor mounted inside a main body, and then filters dust inside the main body.

The vacuum cleaner includes a suction nozzle for sucking dust-containing air, a vacuum cleaner main body communicating with the suction nozzle, an extension pipe for guiding air sucked from the suction nozzle to the vacuum cleaner main body, And a connection pipe connecting the air passing through the extension pipe to the cleaner main body. The cleaner body is equipped with a dust separator for separating dust from air. The dust separating apparatus comprises a dust separating unit and a dust collecting apparatus in which separated dust is stored.

The air containing the dust sucked through the suction nozzle is sequentially transferred to the dust separator through the extension pipe, the handle, and the connection pipe.

However, according to the conventional cleaner, when large dust such as a toilet paper is sucked into the dust separating unit, the suctioned dust is caught by the dust separating unit to block the flow path, so that the suction performance may be lowered.

In addition, when relatively large dust is caught by the dust separating unit, the user must remove the dust while the dust separating unit is disassembled, which is troublesome for the user.

The present invention has been proposed in order to solve the above-described problems, and it is an object of the present invention to provide a vacuum cleaner capable of separating large dust such as a toilet paper before the air is introduced into the dust separating unit, The suction device of the present invention.

According to an aspect of the present invention, there is provided a dust separator for a vacuum cleaner, including: a dust collecting device for storing dust; A dust separating unit disposed outside the dust collecting apparatus, the dust separating unit separating dust from air discharged from the dust collecting apparatus and having a plurality of suction units; And a suction guide pipe disposed outside the dust collecting device for guiding air to the dust collecting device, wherein the dust collecting device comprises: a dust storing part for storing dust separated from the dust separating unit; A dust collecting body having a flow guide part formed with a plurality of branch flow paths communicating with the dust collecting body; A cover member covering the dust collecting body and having a plurality of discharge portions for discharging air of the plurality of branch flow paths; And a partition formed in the flow guide portion to form a separation chamber for separating dust from the air sucked into the flow guide portion. The air flows to the flow guide portion by the suction guide pipe.

According to another aspect of the present invention, there is provided a vacuum cleaner dust separation apparatus comprising: a dust separation unit; And a dust collecting device for guiding air containing foreign matter into the dust separating unit and storing dust separated from the air introduced into the dust separating unit, wherein the dust collecting device comprises: A flow guiding part for introducing the contained air and a dust storing part for storing the dust separated from the dust separating unit, and the flow guiding part is provided with a partition for forming a separation chamber for separating dust from the introduced air, Is formed.

According to the proposed embodiment, since the dust and the like and the large dust are separated from the flow guide portion before moving to the dust separating unit, large dust can be introduced into the dust separating unit to prevent the dust separating unit from being clogged.

In addition, since the foreign matter separated from the flow guide portion can be discharged to the outside at the same time as the foreign matter stored in the dust storage portion is discharged while the cover member is separated from the dust collecting body, There is an advantage in that it can be removed.

Hereinafter, embodiments will be described in detail with reference to the drawings.

1 is a perspective view of a dust separator for a vacuum cleaner according to an embodiment of the present invention.

Referring to FIG. 1, a dust separator 1 for a vacuum cleaner according to the present embodiment includes a dust separator unit 10 for separating dust from the inhaled air, a dust separator 10 for separating dust from the dust separator unit 10, And a suction guide pipe 30 for guiding the movement of air containing dust to the dust collecting device 20. [

In detail, the suction guide pipe 30 guides the air sucked from a suction nozzle (not shown) to be moved to the dust collecting device 20. The air introduced into the dust collecting apparatus (20) is guided to the dust separating unit (10).

The suction guide pipe 30 may be provided on a cleaner body (not shown). As the dust collecting device 20 is attached to the cleaner main body, it communicates with the suction guide pipe 30.

The dust separating unit 10 includes a cylindrical cyclone unit 110 for separating dust in the air by the cyclone principle.

A pair of suction portions 120 are formed on both sides of the cyclone portion 110 to allow air to be sucked into the dust separating unit 10. The pair of suction units 120 may be formed in the tangential direction of the cyclone unit 110 so as to generate a cyclone flow in the cyclone unit 110.

The dust collecting device 20 is provided with a flow guide portion (to be described later) that divides air into the pair of suction portions 120 to flow.

The dust outlet 130 is formed at the center of the cyclone 110 so that the dust separated from the inside of the cyclone 110 is discharged.

Accordingly, the dust in the air sucked from both sides of the cyclone unit 110 through the respective suction units 120 is separated from the air by the cyclone flow and moves to the center of the cyclone unit 110. Then, the moved dust is discharged to the dust collecting apparatus 20 through the dust discharging unit 130.

Here, the dust discharging part 130 is formed in the tangential direction of the cyclone part 110 so as to smoothly discharge the dust.

Accordingly, as the dust separated from the cyclone portion 110 is discharged in the tangential direction of the cyclone portion 110, that is, in the same direction as the direction in which the dust is rotated, the dust having a relatively large density can be easily So that the dust having a relatively small density can be easily discharged from the cyclone part 110.

Further, as the dust having a small density is easily discharged, dust having a small density is prevented from accumulating on the filter member to be described later, so that the air can smoothly flow, thereby further improving the dust separation performance.

A pair of air discharge units 140 are formed on both sides of the cyclone unit 110 to discharge the dust-separated air from the cyclone unit 110. The air discharged through the air discharge unit 140 flows into the main body of the cleaner in a combined state.

Meanwhile, the dust collecting device 20 is a part for storing the dust separated from the dust separating unit 10. The dust collecting device 20 is connected to the dust separating unit 10 as it is mounted on the cleaner main body.

Hereinafter, the structure of the dust separator will be described in more detail.

2 is a cross-sectional view taken along line I-I 'of FIG.

Referring to FIG. 2, a pair of suction portions 120 are formed at both ends of the cyclone portion 110. Each of the suction units 120 is formed in a tangential direction of the cyclone unit 110.

Accordingly, a pair of cyclone flows corresponding to each other is formed in the cyclone part 110 as air is sucked through the respective suction parts 120.

As the pair of cyclone flows are generated in a single space as described above, the flow channel area of the air is increased, and thus the channel loss of the air is reduced, so that the separation performance can be increased.

In addition, the pair of cyclone flows are generated at both sides of the cyclone part 110, respectively, and are moved to the center part, and the respective cyclone flows meet at the center part. Accordingly, strong cyclone flow is generated in the central part of the cyclone part 110 than in the cyclone flow generated in the suction part 120 side.

Accordingly, when the pair of cyclone flows are collected at the central portion of the cyclone portion 110, the flow strength becomes larger than when a single cyclone flow is generated in the same space, so that the separation performance of dust can be further improved do.

The dust moved to the central portion of the cyclone portion 110 can be discharged to the dust collecting container 20 through the dust discharging portion 130 by a strong cyclone flow, .

Particularly, dust such as hair can be easily adhered to the inlet side or inside of the dust discharging part 130 by static electricity. As a strong cyclone flow is generated at the dust discharging part 130 side as described above, Hair or the like can be smoothly discharged to the dust collecting apparatus 20 without being attached to the dust discharging unit 130.

An enlarged tube portion 112 is formed at the central portion of the cyclone portion 110 so as to be larger than the portion having a different diameter. The dust discharging portion 130 is formed in the bulging portion 112.

As a result of forming the tube portion 112 at the central portion of the cyclone portion 110 as described above, a pair of cyclone flows generated from both sides of the cyclone portion 110 are easily gathered at the tube portion 112 . In addition, when the cyclone flow smoothly collects in the bulb portion 112, dust can be smoothly discharged through the dust discharging portion 130.

On both sides of the cyclone part 110, a discharge hole 116 through which the dust separated air is discharged from the cyclone part 110 is formed.

A filter member 150 for filtering the air to be discharged is coupled to each of the exhaust holes 116. In detail, the filter member 150 is formed in a cylindrical shape and has a coupling part 152 which is fastened to the inside of the cyclone part 110 and a coupling part 152 which is extended from the coupling part 152 to filter air, And a filter unit 154 formed thereon. A plurality of through holes 156 through which the air flows are formed in the filter unit 154.

Therefore, the dust-separated air in the cyclone part 110 is discharged from the cyclone part 110 through the discharge hole 116 through the through hole 156. [

In this case, air is sucked through the suction unit 120 without being discharged through the coupling unit 152, so that the air can be smoothly rotated in the cyclone unit 110 without being discharged.

That is, the rotation of the sucked air is guided by the coupling part 152, so that the cyclone flow can be smoothly generated in the cyclone part 110, thereby improving the dust separation performance.

The structure of the dust collecting apparatus will be described below.

3 and 4 are perspective views of the dust collecting apparatus according to the present embodiment, FIG. 5 is a perspective view of the dust collecting body according to the present embodiment, and FIG. 6 is a sectional view taken along line II-II 'of FIG.

3 to 6, the dust collecting apparatus 20 according to the present embodiment includes a dust collecting body 210 and a cover member 250 coupled to the dust collecting body 210 on the upper side.

In detail, the dust collecting body 210 includes a first wall 211 forming an overall contour and a second wall 212 dividing an inner space of the first wall 211 into two spaces.

A dust storage part 220 for storing dust separated from the dust separation unit 10 is formed on one side (left side in FIG. 5) of the second wall 212, 5, a flow guide part 230 is formed to divide the air introduced into the dust collecting body 210 into branching parts.

The cover member 250 is coupled to an upper side of the dust collecting body 210. The inner space of the dust storage part 214 and the flow guide part 250 is simultaneously shielded while the cover member 250 is coupled to the upper side of the dust collection body 210.

The cover member 250 is formed with a dust inlet hole 252 through which air moving along the dust outlet 130 flows into the dust storage 214. In addition, the cover member 250 is formed with a pair of air discharge holes 254 and 256 through which the air in the flow guide part 230 is discharged. That is, the air discharge holes 254 and 256 are formed in the same number as the suction unit 120 of the dust separation unit 10.

In this respect, the flow guide unit 230 will be described in more detail.

The flow guide unit 230 separates large dust such as dust from the air introduced from the suction guide pipe 30.

A depression (232) is formed on the lower side of the flow guide part (230). The depressed portion 232 is depressed upwardly from the bottom surface of the flow guide portion 230. The depression (232) is formed with an air inlet hole (233) through which the air of the suction guide pipe flows.

A partition 240 is formed in the flow guide part 230 to define a separation chamber 246 in which relatively large dust is separated from the air introduced through the air inlet hole.

In detail, the partition 240 is formed in a " C " The partition 240 includes a pair of extended portions 241 and 242 extending from the inner wall of the flow guide portion 230, that is, the second wall 212, and the pair of extended portions 241 And 242, respectively.

The connection portion 245 is spaced from the bottom surface 230a of the flow guide portion 230. [ The connection portion 245 and the pair of extension portions 241 and 242 are separated from the inner wall of the flow guide portion 230, that is, the first wall 211 forming the flow guide portion 230 . Branch flow passages 247 and 248 are formed on both sides of the pair of extension portions 241 and 242.

The air on the branched flow paths 241 and 242 is transferred to the suction unit 120 of the dust separation unit 10 through the air discharge holes 254 and 256.

The extension portions 241 and 242 are formed with through holes 243 and 244 through which a part of air on the separation chamber 246 is bypassed by the branched flow paths 247 and 248. The through holes 243 and 244 are positioned adjacent to the cover member 250 in a state where the cover member 250 is coupled to the dust collecting body 210. That is, the through holes 243 are positioned adjacent to the respective air discharge holes 254 and 256.

As the through holes 243 and 244 are formed in the extension portions 241 and 243 as described above, a part of the air in the separation chamber 246 is bypassed to the branch passages 247 and 248, 246 are prevented from falling downward and the large dust that has fallen is prevented from moving to the air discharge holes 254, 256.

The cover member 250 is formed with a latching portion 258 for catching large dust such as rests or the like in the air introduced into the separation chamber 246. The engaging portion 258 extends downward from the bottom surface of the cover member 250 by a predetermined length. The cover member 250 is positioned in the space between the pair of extensions 241 and 242 in a state where the cover member 250 is coupled to the dust collecting body 210.

7 is a vertical cross-sectional view in a state where the flow guide portion and the suction guide pipe are connected to each other according to the first embodiment.

Referring to FIG. 7, the suction guide pipe 30 is connected to a lower side of the flow guide part 230. The suction guide pipe (30) is formed by bending. As the suction guide pipe is bent, the suction guide pipe 30 is divided into a portion 301 having a large radius of curvature and a portion having a small radius of curvature 302 in a vertical section.

A guide rib 303 for guiding a flow of light dust such as a toilet paper is formed at a portion where the radius of curvature of the suction guide pipe 30 is large. The guide leads are formed in a predetermined length in the longitudinal direction of the suction guide pipe (30). The guide ribs 303 extend toward a small portion of the suction guide pipe 30 at a large radius of curvature. One or more of the guide ribs 303 may be formed.

The dust flowing through the suction guide pipe 30 is moved along the portion 301 having a large radius of curvature due to the inertia force.

The heavy dust moving along the portion 301 having a large radius of curvature is introduced into the space between the connection chamber 245 and the first wall 211 through the air inlet hole 203, 249).

On the other hand, the light dust such as the rest is moved along the guide rib 303. Light dust moving along the guide rib 303 is moved to the separation chamber 246 through the air inlet hole 233.

That is, the guide rib 303 guides the light dust such as the rest of the dust flowing in the suction guide pipe 30 to the separation chamber 246.

Hereinafter, the operation of the dust separator will be described.

When the suction force is generated in the main body of the cleaner, air containing dust is moved along the suction guide pipe (30). The dust-containing air moving along the suction guide pipe 30 flows into the flow guide unit 250 through the air inlet hole 253.

At this time, among the dusts guided by the guide ribs 303, light dust such as dust is suctioned through the air inflow hole 233 and then moved to the separation chamber 246 as described above. In addition, some of the heavy dust enters the separation chamber 246.

The light dust, such as a resting motion, moved to the separation chamber 246 rises in a state in which the inertia force is maintained and is caught by the catching part 258.

Part of the heavy dust and air moved to the separation chamber 246 is transferred to the respective branched flow paths 247 and 248 through the through holes 243 and 254. The other part of the heavy dust and air is shifted downward by about 180 degrees in the flow direction by the cover member 250 and then moved to the branch flow paths 247 and 248.

At this time, dusts such as dust and the like in the separation chamber 246 are moved downward by the air moved from the separation chamber 246 to the branched flow paths 243 and 244 through the respective through holes 243 and 244 So that the engagement state of the engagement portion 258 is maintained.

Air and dust introduced into the branched flow paths 247 and 248 are transferred to the suction unit 120 of the dust separation unit 10 through the air discharge holes 254 and 256.

The air moved to each of the suction units 120 is sucked in the tangential direction on both sides of the cyclone unit 110.

The air sucked into the cyclone unit 110 is moved to the center of the cyclone unit 110 while being rotated around the inner circumferential surface of the cyclone unit 110. During this process, air and dust are subjected to different centrifugal forces But they are separated from each other.

The separated dust is discharged to the dust discharging part 130 in a tangential direction at the center of the cyclone part 110. The discharged dust is moved along the dust discharging part 130, 252 to the inside of the dust storage part 220 of the dust collecting device 20.

On the other hand, the dust-separated air is filtered through the through-holes 156 of the filter member 150 and then discharged from the cyclone portion 110 through the discharge holes 116. The discharged air is moved along the air discharging part 140 and flows into the cleaner main body.

Meanwhile, the cover member 250 is separated from the dust collecting body 210 to discharge the dust of the dust storing unit and the separating unit to the outside. Thereafter, the dust collecting body 210 is turned over. Dust from the dust storage part 220 and the separation part 230 is simultaneously discharged to the outside.

Accordingly, the dust of the flow guide unit 230 can be emptied together with the user while the dust stored in the dust storage unit 220 is emptied. Therefore, the convenience of the user is increased.

According to the present embodiment as described above, large dust such as dust or the like is caught in the separation chamber provided in the flow guide part 230, and large dust is not introduced into the dust separation unit 10. As a result, large dusts are prevented from being introduced into the dust separating unit (10).

8 is a perspective view of the dust collecting body according to the second embodiment.

The present embodiment is the same as the first embodiment in the other portions, except that there is a difference in the configuration of the flow guide portion. Therefore, only the characteristic parts of the present embodiment will be described below, and the same parts as those of the first embodiment will be described as the contents of the first embodiment.

Referring to FIG. 8, the dust collecting body 410 according to the present embodiment includes a dust storing portion 420 and a flow guide portion 430. A pair of partitioning portions 441 and 442 for forming a separation chamber 436 is formed in the flow guide portion 430. The pair of partition portions 441 and 442 are spaced apart from each other by a predetermined distance. One end of each of the dividing sections 441 and 442 is formed integrally with a first wall 411 forming the flow guide section 430 and the other end of the dividing sections 441 and 442 is connected to the flow guide section 430. [ Is formed integrally with a second wall (412) that forms a second wall (430). That is, each of the plurality of partition portions 441 and 442 is formed integrally with the inner circumferential surface of the flow guide portion 430. The partitioning portions 441 and 442 are formed with through holes 443 through which air in the separation chamber is bypassed to the branch flow paths 437 and 438.

Therefore, according to the present embodiment, light dust moving along the suction guide pipe can be moved to the separation chamber without forming a guide member in the suction guide pipe.

9 is a cross-sectional view showing the internal structure of the flow guide portion according to the third embodiment.

The present embodiment differs from the second embodiment in that the guide member is formed so that dust is moved to the separation chamber inside the flow guide portion. Therefore, only the characteristic parts of the present embodiment will be described below, and the same parts as those of the first embodiment will be described as the contents of the first embodiment.

9, a guide member 434 for moving the air sucked into the flow guide portion 430 through the air inlet hole to the separation chamber 436 is formed in the flow guide portion 430 of the present embodiment . The guide member 434 is provided in the shape of a tube and extends upward at the rim of the air inlet hole 433. A part of the guide member 434 is positioned inside the separation chamber 436.

Therefore, according to the present embodiment, the light dust moving along the suction guide pipe can be completely moved to the separation chamber.

10 is a perspective view of the dust collecting body according to the fourth embodiment.

The present embodiment is the same as the third embodiment in other portions, but differs in the structure of the dividing portion.

Referring to FIG. 10, the dust collecting body 510 according to the present embodiment includes a dust storing portion 520 and a flow guide portion 530. A partition 540 for forming a separation chamber 536 is formed in the flow guide part 530. A portion of the guide member 534 extending from the edge of the air inflow hole is positioned inside the partition 540.

In detail, the partition 540 has a circular horizontal section. The diameter of the partitioning part 540 is larger than the width of the flow guide part 530. Therefore, a part of the partitioning part 540 protrudes outside the flow guide part 530, and another part protrudes toward the dust storage part 520 side.

According to the present embodiment as described above, the flow path cross-sectional area of the partitioning portion 540 is significantly larger than that of the guide member 543, so that the flow velocity of the air in the separation chamber 536 is reduced from the guide member 543 As compared with the flow rate of the gas. Therefore, light dust such as dust and the like discharged to the separation chamber 536 stays in the separation chamber 536 and does not fall downward from the separation chamber 536.

1 is a perspective view of a dust separator of a vacuum cleaner according to the present embodiment.

FIG. 2 is a cross-sectional view taken along line I-I 'of FIG. 1; FIG.

3 and 4 are perspective views of a dust collecting apparatus according to the present embodiment.

5 is a perspective view of the dust collecting body according to the embodiment.

6 is a cross-sectional view taken along line II-II 'of FIG. 3;

7 is a vertical cross-sectional view of the flow guide portion and the suction guide pipe connected to each other according to the first embodiment;

8 is a perspective view of the dust collecting body according to the second embodiment.

9 is a sectional view showing the internal structure of the flow guide portion according to the third embodiment.

10 is a perspective view of a dust collecting body according to the fourth embodiment;

Claims (11)

A dust collecting device for storing dust; A dust separating unit disposed outside the dust collecting apparatus, the dust separating unit separating dust from air discharged from the dust collecting apparatus and having a plurality of suction units; And And a suction guide pipe disposed outside the dust collecting device and guiding air to the dust collecting device, The dust collecting apparatus includes a dust collecting body having a dust storing portion for storing dust separated from the dust separating unit and a flow guide portion for forming a plurality of branch flow paths communicating with the respective suction portions. A cover member covering the dust collecting body and having a plurality of discharge portions for discharging air of the plurality of branch flow paths; And And a partition formed in the flow guide portion to form a separation chamber for separating dust from the air sucked into the flow guide portion, And the air flows into the flow guide portion by the suction guide pipe. The method according to claim 1, Wherein the flow guide portion includes an air inlet hole through which the air flowing through the suction guide pipe flows and a guide member extending from the air inlet hole toward the cover member side. The method according to claim 1, And a through hole is formed in the partition to allow air in the separation chamber to be bypassed by the branch flow paths. The method according to claim 1, Wherein the partition portion includes a plurality of extension portions extending from an inner circumferential surface of the flow guide portion, And a connecting portion connecting the extension portion. The method according to claim 1, A plurality of partitioning portions are provided, And both ends of the partition are integrally formed with the inner circumferential surface of the dust collecting body. The method according to claim 1, Wherein the partition has a horizontal cross section formed in a circular shape. The method according to claim 1, Wherein the suction guide tube is formed with a guide rib for guiding air containing foreign matter into the separation chamber. The method according to claim 1, Wherein the dust storage portion and the flow guide portion are integrally formed. delete delete delete

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