KR100816911B1 - Dust separating apparatus of vacuum cleaner - Google Patents

Abstract

A dust separating apparatus of a vacuum cleaner is provided to form a plurality of air suction units regardless of position by forming the air sucking units at two sides of a cyclone unit. A dust separating apparatus of a vacuum cleaner comprises a dust separating unit(10), a dust discharge unit(140), a discharge hole(112), and a dust container(20). The dust separating unit is provided with at least one hole on its surfaces which face each other in parallel. Air is sucked through the holes. The dust discharge unit is configured to discharge dust separated through the dust separating unit. The discharge hole is configured to discharge air separated through the dust separating unit. The dust container is connected with the dust discharge unit so that the separated dust piles up.

Description

Dust separating apparatus of vacuum cleaner

1 is a perspective view schematically showing the configuration of a dust separation apparatus of a vacuum cleaner according to a first embodiment.

Figure 2 is a perspective view of the dust collecting container is separated from the dust separator.

3 is a cross-sectional view taken along the line II ′ of FIG. 1.

4 is a cross-sectional view taken along the line II-II 'of FIG. 1;

5 is a cross-sectional view taken along line III-III 'of FIG. 1;

Figure 6 is a perspective view schematically showing the configuration of a dust separation apparatus of a vacuum cleaner according to a second embodiment of the present invention.

FIG. 7 is a cross-sectional view taken along line III-III ′ of FIG. 6;

8 is a cross-sectional view taken along line IV-IV 'of FIG. 6;

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

110: cyclone unit 120, 130: air intake unit

140: dust outlet 150: air outlet

The present invention relates to a dust separation apparatus of a vacuum cleaner, and more particularly, to a dust separation apparatus of a vacuum cleaner in which suction power is improved.

In general, a vacuum cleaner is a device that sucks air containing dust by using a vacuum pressure generated by a suction motor mounted inside the body, and then filters the dust inside the body.

Such a vacuum cleaner may be distinguished by a canister method in which a nozzle part, which is a large suction port, is provided separately from the main body and connected by a connection pipe, and an upright method in which the nozzle part is integrally formed with the main body.

On the other hand, a conventional vacuum cleaner includes a cleaner body and a dust collecting device mounted on the cleaner body to store dust separated from the air. Such a dust collector is mainly configured to separate dust by the cyclone principle.

The performance of the vacuum cleaner configured as described above may be substantially determined according to the height of the dust separation performance, and the dust separation performance may be determined by the suction force. Therefore, a vacuum cleaner has been proposed to continuously improve the suction power.

On the user side, the dust collecting device should be separated from the cleaner powder to allow the user to easily discharge dust.

The present invention is proposed under the background as described above, and an object of the present invention is to propose a dust separation apparatus of a vacuum cleaner to improve the suction power, and thus to improve the dust separation performance.

In addition, an object of the present invention is to propose a dust separation apparatus of a vacuum cleaner to simplify the structure of the dust collecting container in which dust is stored so that the user can easily discharge the dust.

Dust separation apparatus of the vacuum cleaner according to the present invention for achieving the object as described above is at least one through hole is formed on each of the surfaces facing each other, the dust separation unit through which the air is sucked through the through hole; A dust discharge unit configured to discharge dust separated from the dust separation unit; A discharge hole for discharging air separated from the dust separation unit; And a dust container communicating with the dust discharge part to store the separated dust.

Dust separation apparatus of the vacuum cleaner of the present invention according to another aspect is formed in a position spaced apart from each other having a plurality of through-holes for allowing air to be sucked; A dust discharge unit configured to discharge dust separated from the dust separation unit; At least one discharge hole through which dust separated air is discharged to the dust separation unit; And a dust collecting container communicating with the dust discharge part to store the separated dust, wherein the flow direction of the air sucked through the through hole and the flow direction of the air discharged through the air discharge hole are opposite to each other. It features.

Hereinafter, with reference to the drawings will be described a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is a perspective view schematically showing a configuration of a dust separation apparatus of a vacuum cleaner according to a first embodiment, and FIG. 2 is a perspective view of a dust collecting container separated from the dust separation apparatus.

1 and 2, the dust separator of the vacuum cleaner according to the present invention includes a dust separator 10 for separating dust from sucked air, and dust separated from the dust separator 10. A dust collection vessel 20 is included for storage.

In detail, the dust separation unit 10 includes a cylindrical cyclone unit 110 in order to separate the dust in the air by the cyclone principle.

In addition, in the present invention, the cyclone unit 110 is arranged in a divided manner. That is, a pair of planes constituting the cyclone part 110 are located at both sides.

In addition, a pair of air suction units 120 and 130 are formed on both side surfaces of the cyclone unit 110 to allow air to be sucked into the dust separation unit 10, respectively. That is, four air intakes are provided in the present invention. Hereinafter, it means "a pair of air intakes (120, 130)" refers to all the air intakes formed on both sides of the cyclone portion (110).

In addition, the pair of air intake parts 120 and 130 are symmetrical with respect to the central axis of the cyclone part 110. Here, since the shapes of the respective air intake parts are the same, only the structure of the one air intake part 120 formed on one side surface of the cyclone part 110 will be described in detail below.

Here, a flow path through which air is sucked into each air suction unit will be described. Although not shown, air containing dust is sucked into the cleaner body by the suction nozzle, and the sucked air flows into a single flow path and then branches. And may be connected to each suction unit.

On the other hand, the air sucked into the cleaner body may be introduced into a single flow path and then branched into two flow paths on both sides of the cyclone part, and then the flow path may be branched again from the branched flow path to be connected to each of the suction parts. The present invention reveals that the flow path of the air sucked into the air intake is not limited.

That is, the dust separation apparatus according to the present invention is characterized in that the air is sucked into the dust separation unit 10 through a pair of air intake unit (120, 130) on both sides.

As described above, when air is sucked through the plurality of air suction units, the suction force may be increased. That is, since the air can flow through the plurality of air intakes, the air flows smoothly, and the suction force can be increased.

In addition, as the air flows smoothly, the dust separation performance in the dust separation unit 10 may be increased. That is, as the air flows smoothly, cyclone flow may be generated smoothly in the dust separation unit 10, and dust separation may be performed smoothly by smooth cyclone flow, thereby improving dust separation performance. It can be.

In addition, the cyclone part 110 in the present invention is formed with a total of four air intake, it is possible to form more air intake than this.

That is, in the case of the present invention, since the air suction parts are formed on both sides of the cyclone part 110, the air suction part can be added without restriction of the position, and the air suction part can be formed without a large change in the size of the dust separation device. do.

On the other hand, in the central portion of the cyclone portion 110, a dust discharge portion 140 for discharging the dust separated in the cyclone portion 110 is formed to extend.

Therefore, dust in the air sucked from both sides of the cyclone unit 110 through the pair of air intake units 120 and 130 is separated from the air by the cyclone flow to form a central portion of the cyclone unit 110. Go to. Then, the moved dust is discharged to the dust collecting container 20 through the dust discharge unit 140.

Here, the dust discharge unit 140 is formed in the tangential direction of the cyclone unit 110 to facilitate the discharge of dust.

Therefore, as the dust separated from the cyclone unit 110 is discharged in the tangential direction of the cyclone unit 110, that is, the dust is discharged in the same direction as the dust was rotated, the dust having a relatively high density is easy. In addition to being easily discharged, dust having a relatively low density can also be easily discharged from the cyclone unit 110.

In addition, since the low-density dust is easily discharged, the low-density dust is not accumulated in the filter member to be described later, so that the air can be smoothly flowed, and thus the dust separation performance can be further improved. .

And, on both sides of the cyclone portion 110 is formed an air discharge unit 150 for discharging the air is separated from the cyclone unit 110, respectively. At this time, the pair of air intake parts 120 and 130 are formed at both sides with respect to the air discharge part 150.

Meanwhile, the dust collecting container 20 communicates with the dust separating unit 10 as the dust collecting container 20 is mounted on the cleaner body. In addition, when the dust collecting container 20 is mounted on the cleaner body, the dust collecting container 20 is located under the dust separation unit 10.

Accordingly, the dust inlet 210 is formed on the dust collecting container 20. In addition, the dust discharge unit 140 extends downward from the cyclone unit 110.

Therefore, since the dust separated from the cyclone unit 110 moves downward along the dust discharge unit 140, the separated dust can be easily introduced into the dust collecting container 20.

In addition, a cover member 30 is coupled to the dust collecting container 20 to discharge dust stored therein. The cover member 30 may be rotatably coupled to the dust collecting container 20, and may be detachably coupled to the dust collecting container 20. Note that the present invention is not limited to the method of coupling the cover member 20.

Thus, the dust collecting container 20 according to the present invention is provided as a separate article and the dust separation unit 10 is configured to selectively communicate with the dust separation unit 10.

Therefore, the user may separate only the dust collecting container 20 to discharge dust stored in the dust collecting container 20 to the outside.

In addition, only a space for storing the dust separated by the dust separation unit 10 is formed inside the dust collecting container 20. Therefore, the structure of the dust collecting container 20 is simplified and the weight of the dust collecting container 20 is minimized.

In addition, since the weight of the dust collecting container 20 is minimized, the user can easily lift or handle the dust collecting container 20, and as the internal structure of the dust collecting container 20 is simple, the stored dust is stored outside. As it can be discharged smoothly, the user can easily clean the interior of the dust collecting container (20).

Hereinafter, the dust separation apparatus according to the present invention will be described in more detail.

3 is a cross-sectional view taken along line II ′ of FIG. 1, FIG. 4 is a cross-sectional view taken along line II-II ′ of FIG. 1, and FIG. 5 is a cross-sectional view taken along line III-III ′ of FIG. 1. .

3 to 5, as described above, a pair of air suction units 120 and 130 are formed at both ends of the cyclone unit 110.

In addition, the air suction unit 120 may include a through hole 122 formed at a side surface of the cyclone unit 110 and a flow guide extending from the through hole 124 to the outside of the cyclone unit 110. 124).

In detail, the flow guide 124 guides the cyclone flow to be generated while the air is sucked into the cyclone unit 110.

That is, when the through-hole is formed on the side of the cyclone portion 110, since the air flows in the axial direction of the cyclone portion 110, it is difficult to generate cyclone flow in the cyclone portion 110 Therefore, the flow guide 124 is formed so that the sucked air can flow along the inner circumferential surface of the cyclone part 110.

In addition, the flow guide 124 extends along a predetermined curvature in the through hole 122 and extends along the side surface of the cyclone part 110. That is, air flows along both sides of the cyclone part 110 along the flow guide 124 and then flows into the cyclone part through the through hole.

In addition, the through hole 122 is formed in a substantially semi-circular shape so that the flow direction of air moving along the flow guide 124 can be maintained.

Therefore, as air is sucked through the plurality of air intakes 120 and 130, a pair of cyclone flows are formed on both sides of the cyclone part 110. At this time, since the air sucked individually through each of the air intakes (120, 130) is merged in the cyclone unit 110, a large pair of cyclone flow inside the cyclone unit 110 It can be understood that this is formed.

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

As a pair of cyclone flows are generated in a single space, the size of the cyclone portion may be smaller than that of a structure in which one cyclone flow is generated as in the related art.

At this time, even if the size of the cyclone unit 110 is made small, since the centrifugal force generated at the air intake unit 120 and 130 becomes larger than before, the dust separation performance may be improved.

In addition, as a pair of cyclone flows are generated in a single space, it is possible to obtain the same dust separation performance as a structure in which a conventional air passes through a plurality of dust separation units, and thus, dust from the air discharged from the dust separation unit. No additional dust separator is required to separate the dust again. However, of course, the present invention may further provide an additional dust separator.

In addition, a pair of cyclone flows are generated at both sides of the cyclone portion 110 and move to the center portion, and the cyclone flows meet at the center portion. Accordingly, a stronger cyclone flow is generated in the central portion of the cyclone portion 110 than the cyclone flow generated from the air intake portions 120 and 130.

Therefore, when a pair of cyclone flows are collected at the center portion of the cyclone part 110, the flow strength is increased than when a single cyclone flow occurs in the same space, so that dust separation performance can be further improved. do.

In addition, the dust moved to the central portion of the cyclone unit 110 may be discharged to the dust collecting container 20 through the dust discharge unit 140 by a strong cyclone flow, so that the dust discharge performance It can be improved.

In particular, foreign matter such as hair can easily adhere to the inlet side or the inside of the dust discharge unit 140 by static electricity, as the strong cyclone flow occurs in the dust discharge unit 140 as described above Foreign matter such as hair does not adhere to the dust discharge unit 140, and can be smoothly discharged to the dust collecting container 20.

On the other hand, on both sides of the cyclone portion 110, the air discharge hole 112 (see Fig. 2) through which the air from which the dust is separated from the cyclone portion 110 is discharged.

And, each of the air discharge hole 112 is coupled to the filter member 160 for filtering the discharged air. In detail, the filter member 160 is formed in a cylindrical shape, a fastening part 162 fastened to the inside of the cyclone part 110, and extends from the fastening part 162 to filter air and have a conical shape. It is composed of a filter unit 164 formed. In addition, the filter unit 164 is provided with a plurality of through-holes 166 through which air flows.

Therefore, the air from which dust is separated from the cyclone unit 110 is discharged from the cyclone unit 110 through the discharge hole 112 via the through hole 166.

In this case, since the through hole is not formed in the fastening part 162, the air sucked through the air suction parts 120 and 130 may be smoothly rotated inside the cyclone part 110 without being immediately discharged. .

That is, by the fastening part 162, the rotation of the sucked air is guided so that the cyclone flow can be generated smoothly inside the cyclone part 110, thereby improving the dust separation performance.

Further, since the through-holes 122 through which air is sucked and the discharge holes 112 through which the air is discharged are formed on both side surfaces of the cyclone part, the flow direction of the air sucked through the through-holes 122 is the discharge hole ( The flow direction of the air drawn in through 112 is reversed.

On the other hand, the distance (L1) between the pair of filter members 160 provided in the cyclone portion 110 is preferably formed larger than the width (L2) of the dust discharge portion.

In detail, a pair of cyclone flows generated in the cyclone part 110 are collected at the center of the cyclone part 110 as described above, and the dust separated from the air by the cyclone flow is It is discharged through the dust discharge unit 140.

At this time, when the distance (L1) of the pair of filter members 160 is formed smaller than the width (L2) of the dust discharge portion 140, foreign matter such as hair or tissue paper is the dust discharge portion 140 Without being discharged through, it may be stuck to the filter member 160 or caught in the through hole 166. In this case, the air cannot smoothly pass through the filter member 160, and the suction force is lowered.

Therefore, in the present invention, the distance L1 between the pair of filter members 160 is larger than the width L2 of the dust discharge unit 140 so that foreign matter such as hair or tissue is discharged to the dust discharge unit 140. To be completely discharged.

As described above, in the present invention, the air is sucked into the cyclone unit 110 through the plurality of air suction units 120 and 130, and the air from which dust is separated from the cyclone unit 110 is provided in plurality. It is configured to be discharged from the cyclone unit 110 through the air discharge hole 112 of the.

Therefore, as the air sucked into the cyclone unit 110 through each of the air suction units 120 and 130 is discharged through the respective air discharge holes 112, the air can be smoothly discharged.

The smooth discharge of air from the cyclone unit 110 allows the suction force to be substantially increased, and allows the cyclone flow to be smoothly performed within the cyclone unit 110.

In addition, even when dust is accumulated in one filter member and air does not flow smoothly, the air may be discharged through the other filter member, so that the suction performance of the air may be prevented from dropping rapidly.

On the other hand, the cyclone portion 110 is formed with an opening 114 for the replacement of the filter member 160. In addition, the opening 114 is selectively shielded by the cover member 170. In addition, a sealing member 116 is provided at a coupling portion of the opening 114 and the cover member 170.

Here, the cover member 170 is preferably formed so that the inner surface has the same curvature as the inner surface of the cyclone portion 110 in a state coupled to the opening 114.

That is, the inner peripheral surface of the cover member 170 and the cyclone portion 110 is formed continuously.

Therefore, the cyclone flow inside the cyclone portion 110 is prevented from being changed by the cover member 170, and can be kept constant.

As the cover member 170 is detachably coupled to the opening 114, the user may easily replace the filter member 160 by detaching the cover member 170.

Meanwhile, a dust storage unit 202 for storing dust is formed in the dust collecting container 20, and a dust inlet 210 is formed above the dust collecting container 20. At this time, the dust inlet 210 is in communication with the dust discharge unit 140 as the dust collecting container 20 is mounted on the cleaner body.

Therefore, the dust inlet 210 is provided with a sealing member 220 for sealing the contact portion of the dust inlet 210 and the dust outlet 140. At this time, the sealing member 220 may be provided to the dust discharge unit 140.

Here, the dust collecting container 20 is provided as a separate article and configured to selectively communicate with the dust separation unit 10, the dust collecting container 20 within the range that can be mounted on the cleaner body The size of the container 20 can be adjusted.

In this case, by forming the dust collecting container 20 large, the amount of dust stored in the dust storage unit 202 can be increased.

Hereinafter, the operation of the dust separation apparatus according to the present invention will be described.

When suction force is generated in the cleaner body, air containing dust is sucked into the cleaner body. In addition, the sucked air is sucked into the cyclone unit 110 through the respective air suction units 120 and 130 through a predetermined flow path.

Then, the sucked air is moved along the inner circumferential surface of the cyclone portion 110 and moved to the center portion of the cyclone portion 110, in which air and dust are subjected to different centrifugal forces by their weight differences. Separation takes place.

The separated dust (dotted line) is discharged to the dust discharge unit 140 in the tangential direction from the center of the cyclone unit 110, and the discharged dust is moved along the dust discharge unit 140 to collect the dust. It flows into the container 20.

On the other hand, the dust separated air (solid line) is filtered through the through hole 166 of the filter member 160 and is discharged from the cyclone unit 110 through the discharge hole 112. In addition, the discharged air is moved along the respective air discharge parts 150 and introduced into the cleaner body.

6 is a perspective view schematically illustrating a configuration of a dust separation apparatus of a vacuum cleaner according to a second embodiment of the present invention, FIG. 7 is a cross-sectional view taken along line III-III ′ of FIG. 6, and FIG. 8 is a view of FIG. 6. Sectional view taken along IV-IV '.

This embodiment is the same as the original embodiment in other parts, except that there is a difference in the structure of the air intake. Therefore, hereinafter, only characteristic parts of the present embodiment will be described, and reference numerals will be used for the same structure as the original embodiment.

6 to 8, a pair of air intakes 320 and 320 according to the present invention are provided on both sides of the cyclone part 110.

In addition, the air suction unit 320 has a through hole 322 formed at a side surface of the cyclone unit 110, and a suction guide formed outside the cyclone unit 110 at the through hole 322. 324 and a flow guide 326 formed in the through-hole 322 to the inside of the cyclone portion 110.

In detail, the through hole 322 and the suction guide 324 are formed in a circular and cylindrical shape, respectively.

The flow guide 326, the shape is formed in a shape corresponding to the flow guide 124 of the original embodiment, it is provided inside the cyclone portion (110).

In addition, the flow guide 326 is formed to be rounded with a predetermined curvature as shown in FIG. 8 so that air discharged from the flow guide 326 flows along the inner circumferential surface of the cyclone part 110. That is, the curve drawn by the flow guide 326 is formed to be substantially parallel to the curve drawn by the inner circumferential surface of the cyclone part 110.

According to the flow guide 326, the cyclone flow can be generated more smoothly inside the cyclone portion 110 than the original embodiment. That is, since the direction of air flowing along the flow guide 326 is the same as the direction of air rotated in the cyclone part 110, the cyclone flow smoothly in the cyclone part 110. It can happen.

The spirit of the present invention is not limited to the above-described embodiment, and may further suggest other embodiments as follows.

First, the dust collecting container 20 is positioned below the cyclone unit 110 in a state where the dust collecting container 20 is mounted on the cleaner body. Alternatively, the dust collecting container 20 may be located in front of the cyclone unit 110. Can be. In this case, the dust inlet of the dust collecting container 20 may be formed on the side of the dust collecting container 20, it may be located on the upper side of the dust collecting container (20).

In addition, when a dust inlet is formed on the side of the dust collecting container 20, a cover member for discharging dust may be provided on either the upper side or the lower side of the dust collecting container.

In addition, in one embodiment, the dust inlet is formed above the dust collecting container, and the cover member is provided below the dust collecting container, whereas the cover member is provided above the dust collecting container, and the dust inlet is the It may be formed in the cover member. In such a case, the structure of the dust collecting container itself can be further simplified.

In addition, the dust separator and the dust collecting container is communicated only by the dust discharge portion, in addition, a separate bypass passage for communicating the dust separator and the dust collecting container may be further provided. According to the bypass flow path, when a large volume of foreign matter such as a tissue is caught inside the dust discharge unit, the suction force is prevented from being lowered and the flow of air is continuously generated to maintain the suction force at a constant level.

In addition, the filter member is not configured to be coupled to the discharge hole side, the exhaust guide may be formed to guide the discharge of air. That is, the exhaust guide portion is formed in a cylindrical shape like the fastening portion of the original embodiment, the through hole may not be formed.

In addition, a pressurization device for compressing the stored dust may be further provided inside the dust collecting container. The pressurization device may be provided inside the dust collecting container, and may include at least one pressurizing member movable inside the dust collecting container, and a driving device for moving the pressurizing member may be disposed outside the dust collecting container, for example, a cleaner. It may be provided to the body.

In addition, the dust separator may be formed by a single cyclone unit, but alternatively, a pair of cyclone units corresponding to each other may be coupled to each other to form a complete dust separator.

According to the present invention as proposed, the following effects can be obtained.

First, as a plurality of suction portions are formed on both sides of the cyclone portion, a plurality of cyclone flows are generated inside the cyclone portion, thereby increasing the flow path area of the air, thereby reducing the flow path loss of the air. Has an effect of increasing the separation performance.

Second, since the air can be sucked through the plurality of air intakes, the flow of air is made smoothly, and the cyclone flow can be generated smoothly in the cyclone portion, and the separation of dust is facilitated by the smooth cyclone flow. Since it can be made, the dust separation performance can be improved.

Third, as the air intake portions are formed on both sides of the cyclone portion, the plurality of air intake portions can be formed without restriction of the position, and the air intake portions can be formed without a large change in the size of the dust separation device.

Fourth, as the air intake is formed on both sides of the cyclone portion, and the dust discharge portion is formed in the center of the cyclone portion, there is an effect that a strong cyclone flow is generated in the center portion of the cyclone portion can be smoothly discharged dust.

Fifth, since the dust collecting container for storing the dust is provided as a separate article from the dust separating unit, the user only has to empty the dust by separating the dust collecting container, there is an effect that the user's handling of the dust collecting container is improved.

Sixth, since only a space for storing dust is formed inside the dust collecting container, the structure of the dust collecting container is simplified and the weight of the dust collecting container is minimized, thereby improving user convenience.

Seventh, since the internal structure of the dust collecting container is simplified, the dust stored in the dust collecting container can be easily discharged.

Claims (8)

At least one through hole is formed on the surface facing each other, the dust separation unit through which the air is sucked through the through hole; A dust discharge unit configured to discharge dust separated from the dust separation unit; A discharge hole for discharging air separated from the dust separation unit; And The dust separator of the vacuum cleaner is in communication with the dust discharge unit, including a dust collecting container for storing the separated dust. The method of claim 1, The surface facing each other is a dust separation apparatus of the parallel vacuum cleaner. The method of claim 1, The discharge hole is a dust separation device of the vacuum cleaner, respectively formed on the surface facing each other. The method of claim 3, wherein The air suction unit is provided with a plurality on each side, each suction unit is a dust separation apparatus of the vacuum cleaner symmetric with respect to the discharge hole. The method of claim 1, It is formed inside or outside of the through hole to guide the air flow, dust separation apparatus of the vacuum cleaner including a flow guide having a predetermined curvature so that air can flow along the inner peripheral surface of the dust separation unit. A dust separator formed at positions spaced apart from each other and having a plurality of through holes through which air is sucked; A dust discharge unit configured to discharge dust separated from the dust separation unit; At least one discharge hole through which dust separated air is discharged to the dust separation unit; And The dust container is in communication with the dust discharge unit and includes a dust collecting container for storing the separated dust, And a flow direction of the air sucked through the through hole and a flow direction of the air discharged through the air discharge hole are opposite to each other. The method of claim 6, The dust separation unit has a pair of faces facing each other, the communication hole and the air discharge hole dust separation apparatus of the vacuum cleaner is formed on each side. The method of claim 6, The dust separation apparatus of the vacuum cleaner is provided inside or outside the through hole is provided with a flow guide for guiding the suctioned air to move along the inner peripheral surface of the dust separation unit.

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