KR100922716B1 - Dust collecting apparatus of vacuum cleaner - Google Patents

Abstract

This embodiment proposes a dust collector of a vacuum cleaner.

The dust collecting device according to the present embodiment has an opening provided to suck air containing dust, and a dust separator for separating dust from the sucked air, and a dust separator formed at the dust separator to discharge discharged air. A guide is provided to surround the exhaust guide, the exhaust guide, the exhaust member for filtering the air flowing into the exhaust guide, and a guide portion for partitioning the exhaust guide so that the air introduced into the exhaust guide is divided and discharged. do.

cyclone

Description

Dust collecting apparatus of vacuum cleaner

This embodiment relates to a dust collecting apparatus of a vacuum cleaner.

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

The vacuum cleaner includes a dust collecting device detachably mounted to the vacuum cleaner. Modern dust collectors allow the dust to be separated from the air by the cyclone method.

In addition, the performance of the vacuum cleaner may be substantially determined according to the height of the dust separation performance. Therefore, a vacuum cleaner which continuously improves dust separation performance has been proposed. In addition, the user side should be able to easily discharge the dust stored in the dust collector.

Embodiments aim to propose a dust collector of a vacuum cleaner in which air flow is smoothly performed and dust separation performance is improved.

Another object of the embodiment is to propose a dust collector of a vacuum cleaner which can prevent dust from being stored therein and easily empty the dust.

Another object of the embodiment is to propose a dust collecting apparatus of a vacuum cleaner in which the dust collecting capacity is increased.

The dust collecting apparatus of the vacuum cleaner according to one side is provided with an opening to suck the air containing the dust, a dust separation unit for separating the dust from the sucked air, and formed in the dust separation unit of the air separated dust An exhaust guide for guiding the discharge, and an exhaust guide that surrounds the exhaust guide to partition the exhaust member for filtering the air flowing into the exhaust guide and the exhaust guide so that the air introduced into the exhaust guide is divided and discharged; Addition is included.

According to the dust separation apparatus as proposed, there is an advantage that some air and dust sucked along the suction guide may flow smoothly along the inner circumferential surface of the cyclone portion without being discharged directly through the discharge hole.

In addition, as the exhaust guide is formed in the cyclone part, some air and dust sucked along the suction guide are not immediately discharged through the discharge hole.

As such, some air and dust in which the suction guide is sucked are not immediately discharged through the discharge hole, thereby improving the separation performance of the dust in the cyclone portion.

In addition, there is an advantage that the storage capacity of the dust is increased as the dust separated inside the cyclone portion and between the cyclone portion and the dust collecting body.

In addition, since the dust such as the hair is not wound around the exhaust member and the flow preventing portion inside the cyclone portion, the user does not have to remove the dust such as the hair, there is an advantage that can be smoothly discharged to the outside.

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

1 is a perspective view of a dust collecting apparatus according to the present embodiment, and FIG. 2 is a perspective view of an upper unit and a lower unit constituting the dust collecting apparatus separated from each other.

1 and 2, the dust collecting apparatus 1 of the present embodiment, the lower unit 10 for separating the dust primarily from the sucked air and the dust from the air discharged from the lower unit 10 again An upper unit 20 for separating is included.

In detail, the lower unit 10 sucks air containing dust and allows the dust separated from the air to be stored. The lower unit 10 includes a dust collecting body 110 that forms a space in which dust is stored, and a flow guide unit 150 that guides the discharge of air that has undergone dust separation in the internal space of the dust collecting body 110. Included.

The dust collecting body 110 is formed with a suction port 111 to suck the air containing the dust. In addition, a discharge hole 152 through which air is discharged is formed in the flow guide part 150.

The upper unit 20 is coupled to the upper side of the lower unit 10. The upper unit 20 includes a discharge port 233 for discharging air introduced through the through hole 152.

Hereinafter, the structure of the dust collector 1 will be described in detail.

3 is an exploded perspective view of the dust collector.

Referring to FIG. 3, the lower unit 10 includes the dust collecting body 110, a dust separating unit 130 accommodated in the dust collecting body 110 to separate dust from air, and the dust collecting body 110. Coupled to the upper side of the flow guide unit 150 to guide the air discharged from the dust separation unit 130 to the upper unit 20, and is located in the dust separation unit 130 and the Exhaust member 170 for filtering the air discharged from the dust separation unit 130, the lower cover 190 is coupled to the lower side of the dust collecting body 110, the flow preventing portion coupled to the lower cover 190 180 is included.

The upper unit 20 includes an upper cover 210, a filter case 230 coupled to a lower side of the upper cover 210, a filter member 250 accommodated in the filter case 230, and A sealing member 240 for sealing the filter case 230 and the upper cover 210 is included.

In detail, the dust collecting body 110 is formed by opening the upper and lower sides. In addition, an inlet 111 through which air containing dust is sucked is formed on an upper side of the dust collecting body 110. The upper side of the dust collecting body 110 is shielded by the flow guide part 150, and the lower cover 190 is selectively shielded by the lower side of the dust collecting body 110.

The dust separation unit 130 includes a cylindrical cyclone portion 131. A suction guide 132 is formed at an upper side of the cyclone part 131 to allow air sucked into the dust collecting body 110 through the suction port 111 to be sucked into the cyclone part 131. The suction guide 132 extends outward from the side of the cyclone part 110.

When the cyclone part 131 is accommodated in the dust collecting body 110, the suction guide 132 communicates with the suction port 111 and is positioned at the same height as the suction port 111. A discharge hole 135 through which air is discharged is formed on an upper surface of the cyclone part 131.

The flow guide part 150 is coupled to an upper surface of the cyclone part 131. In addition, the flow guide part 150 is formed in a shape recessed downward from the upper surface. Accordingly, the flow guide part 150 includes a circular bottom face 151 and a side portion 152 extending vertically upward from an edge of the bottom face 151.

The bottom portion 151 is formed with a through hole 152 through which air discharged through the discharge hole 135 passes. The through hole 152 is formed at a position corresponding to the discharge hole 135. In addition, a plurality of fastening protrusions 154 are formed on the bottom portion 151 to be fastened by the cyclone portion 131 and a fastening member such as a screw.

In addition, the bottom surface 113 is formed with a plurality of fastening portions 156 for fastening with the dust collecting body 110. The plurality of fastening portions 156 are formed as the bottom portion 151 is recessed upward. That is, the fastening portion 156 protrudes upward from the bottom portion 151.

The exhaust member 170 is formed in a conical shape with an upper side opened. In addition, the exhaust member 170 is fastened to the inner upper surface of the cyclone portion 131. A plurality of holes 172 through which air passes are formed in the side surface of the exhaust member 170.

One side of the lower cover 190 is rotatably coupled to the dust collecting body 110 by a hinge 192, and the other side of the lower cover 190 is detachably coupled to the dust collecting body 110 by a hook 194.

In addition, a coupling guide 196 for coupling the flow preventing part 180 to the upper side of the lower cover 190 is formed. In addition, a plurality of flow preventing ribs 198 are formed on the upper side of the lower cover 190 to prevent the flow of dust.

On the other hand, the filter case 230 has a plurality of through holes 235 through which the air passing through the filter member 250 penetrates is formed on an upper surface thereof. Here, the filter member 250 may be used as a pre-filter as an example, but it is clear that there is no limitation on the type.

In addition, the filter case 230 includes a discharge guide part 236 for discharging air passing through the through hole 235. In addition, an outlet 233 through which air guided by the discharge guide part 236 is discharged is formed on the side of the filter case 230.

The filter member 250 is accommodated in the filter case 230 at the lower side of the filter case 230. The filter member 250 is formed in a substantially cylindrical shape, and is partially cut to prevent interference with the discharge guide part 236 when accommodated in the filter case 230.

The sealing member 240 is formed with a ring-shaped body 241, the coupling portion 242 extending upward from the body 241 is coupled to the outlet 233. In addition, the coupling part 242 is provided with a coupling hole 243 through which the outlet 233 passes. Therefore, in the state in which the outlet 233 is coupled to the coupler 242, the coupler 242 surrounds the circumference of the outlet 233.

Hereinafter, each component of the dust collector 1 will be described in more detail.

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

Referring to FIG. 4, a handle 112 that a user can grasp is formed at the side of the dust collecting body 110. In addition, a lever 116 is provided at a lower side of the dust collecting body 110 to engage with the hook 194 of the lower cover 190.

The lever 116 is located below the suction port 111. In addition, the dust collecting body 110 is provided with a lever support portion 118 to which the hinge shaft 117 of the lever 116 is coupled. In addition, the lever support part 118 is provided with a coupling hole 119 to which the hinge shaft 117 is coupled. The lever 116 is elastically supported by an elastic member (see 122 of FIG. 9).

A plurality of fastening guides 113 for fastening with the fastening part 156 of the flow guide part 150 are formed above the inner circumferential surface of the dust collecting body 110. The plurality of fastening guides 113 extend from the inner circumferential surface of the dust collecting body 110 toward a central portion of the dust collecting body 110 by a predetermined length.

In addition, a fastening hole 115 for fastening the fastening member is formed in the fastening guide 113. In addition, the fastening guide 113 is inserted below the fastening part 156 while the flow guide part 150 shields the upper side of the dust collecting body 110, and the fastening part 156 is It is supported by the fastening guide 113.

5 is a perspective view of the dust separator according to the present embodiment, and FIG. 6 is a plan sectional view of the dust separator of FIG. 5.

5 and 6, the dust separator 130 includes a cylindrical cyclone portion 131 as described above. The cyclone portion 131 is formed by opening the lower side. The discharge hole 135 is formed on the upper surface of the cyclone portion 131.

In addition, a fastening hole 136 for fastening with the fastening protrusion 154 of the flow guide part 150 is formed on a top surface of the cyclone part 131 by a fastening member such as a screw. The fastening hole 136 is formed at a position corresponding to the fastening protrusion 154.

An opening 137 through which air containing dust is sucked is formed at an upper side of the cyclone part 131. In addition, the suction guide 132 guides the air containing dust to flow into the cyclone part 131 through the opening 137.

The suction guide 132 is formed in a substantially tangential direction of the cyclone portion 131. In addition, the suction guide 132 includes an inclined portion 132a which is inclined in the air rotation direction inside the cyclone portion 131. That is, part of the suction guide 132 is formed to be inclined.

Therefore, the width of the flow path on the inclined portion 132a side of the suction guide 132 is smaller than that of the other portions of the suction guide 132.

As such, when the inclined portion 132a is formed in the suction guide 132, the air sucked through the suction guide 132 may smoothly flow along the inner circumferential surface of the cyclone portion 131, and the cyclone There is an advantage that the interference with the air rotating inside the portion 131 is reduced.

In addition, a dust discharge hole 140 is formed in the cyclone part 131 to allow a part of the dust flowing in the spiral in the cyclone part 131 to be discharged to the outside.

The dust discharge hole 140 is formed on the opposite side of the opening 137 with respect to the vertical center axis of the cyclone portion 131 as shown in FIG.

The dust discharge hole 140 is formed long up and down, the width of the upper portion 140a is formed larger than the width of the lower portion 140b. That is, the dust discharge hole 140 is formed to decrease in width from the upper side to the lower side.

In this case, the dust discharge hole 140 includes a first side portion 140c which first meets the dust in the process of rotating the dust, and a second side portion 140d spaced apart from the first side portion 140c. In addition, the first side portion 140c is vertically formed, and the second side portion 140d is inclined in a direction closer to the first side portion 140c as it goes from the upper side to the lower side of the dust discharge hole 140. Lose.

In detail, since the flow velocity of the dust flowing spirally inside the cyclone part 110 is large inside the cyclone part 131, the width of the upper portion 140a of the dust discharge hole 140 is large. The fine dust is smoothly discharged to the outside through the upper portion 140a of the dust discharge hole 140.

In addition, since the flow velocity of dust decreases toward the lower side of the cyclone portion 131, the size of the dust discharge hole 140 is reduced so that the fine dust flows through the lower portion 140b of the dust discharge hole 140. Should be discharged to the outside smoothly.

In addition, by forming the second side portion 140d of the dust discharge hole 140 to be inclined, large dust such as a tissue is prevented from being caught by the second side portion 140d of the dust discharge hole 140. In addition, large dust such as a tissue is moved to the lower side of the cyclone portion 131.

A protruding portion 142 protruding to the outside of the cyclone portion 131 is formed below the cyclone portion 131. The protrusion 142 is formed as the inner circumferential surface of the cyclone portion 131 is recessed outward. A portion of the flow preventing part 180 is accommodated in the inner space of the protrusion 142.

On the other hand, the exhaust guide 144 is formed on the upper surface of the cyclone portion 131 to guide the discharge of air in the cyclone portion 131. In detail, the exhaust guide 144 is formed in a cylindrical shape and protrudes downward from the upper surface of the cyclone portion 131. That is, the exhaust guide 144 extends downward from the edge of the discharge hole 135.

The exhaust guide 144 is formed with a guide portion 145 for guiding the flow of air. The horizontal cross section of the guide part 145 is formed in a straight line with respect to the horizontal cross section of the exhaust guide 144, and divides the internal space of the exhaust guide 144 into two spaces.

In detail, the guide part 145 includes a center part 146 positioned at the vertical center of the exhaust guide, and a pair of guide ribs 147 and 148 extending from the center part 146. The pair of guide ribs 147 and 148 form a straight line. That is, the angle formed by the pair of guide ribs 147 and 148 is 180 degrees. Of course, although the pair of guide ribs 147 and 148 are not straight, the angle formed by the pair of guide ribs 147 and 148 may be formed to be close to 180 degrees.

In addition, the guide part 144 is formed in a direction toward the dust discharge hole 140 from the opening 137 when viewed in a plane projection, that is, from the upper side to the lower side.

In detail, a line A extending horizontally from one end of the guide part 144 passes through the dust discharge hole 140 and a line B extending horizontally from the other end of the guide part 144 is Pass through opening 137.

As described above, as the exhaust guide part 144 extends downward from the upper surface of the cyclone part 131, the air sucked into the cyclone part 131 through the suction guide 132 is discharged. It is possible to prevent the discharge straight through the hole 135.

In addition, as the guide part 145 is formed in the exhaust guide 144, air introduced into the exhaust guide 144 flows divided into both sides of the guide part 145. The stagnation of air at the central portion of 144 is prevented.

In addition, since the guide unit 145 partitions the inner space of the exhaust guide 144 into a plurality of pieces, turbulence in the exhaust guide 144 may be reduced, and thus the noise of air flow may be reduced.

7 is a perspective view of a filter case according to the present embodiment.

Referring to FIG. 7, the filter case 230 includes an upper surface portion 230a and a side portion 230b extending downward from an edge of the upper surface portion 230a. Thus, the filter case 230 is provided with a receiving space 231 of the filter member 250.

A coupling rib 234 to which the sealing member 240 is coupled is formed along the outer circumference of the side surface portion 230b. The coupling rib 234 is formed to be spaced apart from the lower end of the side portion 230b by a predetermined distance.

The discharge guide portion 236 is formed as the upper surface portion 230a is recessed. Therefore, the discharge guide portion 236 protrudes downward from the upper surface portion 230a when viewed from below. The outlet 233 protrudes laterally from the side portion 230b and communicates with the discharge guide portion 236.

In addition, the outlet 233 is provided with an insertion portion 233a into which a part of the sealing member 240 is inserted.

8 is a perspective view of a flow preventing unit according to the present embodiment.

Referring to FIG. 8, the flow preventing part 180 includes a backflow preventing part 182 that prevents backflow of dust, a support part 184 that supports the backflow preventing part 182, and the lower cover 190. It is coupled to include a blocking unit 185 to block the flow of dust.

In detail, the backflow prevention part 182 is formed in a circular shape when viewed from the upper side, and the diameter increases from the upper side to the lower side.

The support part 184 is formed below the backflow prevention part 182 and extends in a radial direction from the center of the backflow prevention part 182.

The blocking part 185 extends to the side of the support part 182. Therefore, when viewed from above, the blocking part 185 protrudes outward of the backflow prevention part 182. An insertion groove 186 for inserting the coupling guide 196 of the lower cover 190 is formed below the blocking unit 185.

In addition, the blocking part 185 is provided with a fastening hole 187 for fastening the fastening member in a state where the coupling guide 196 is inserted into the insertion groove 186.

FIG. 9 is a cross-sectional view taken along line II of FIG. 1, FIG. 10 is a cross-sectional view taken along line II-II of FIG. 1, and FIG. 11 is a cross-sectional view taken along line III-III of FIG. 1.

9 to 11, the cyclone part 131 is accommodated in the dust collecting body 110. In addition, based on the upper surface of the lower cover, the inner upper surface 131a of the cyclone portion 131 is located at the same height as the inner upper surface 132a of the suction guide 132. That is, the inner upper surface 131a of the cyclone portion 131 and the inner upper surface 132a of the suction guide 132 are positioned on the same horizontal line.

In detail, since the discharge hole 135 is formed on the upper surface of the cyclone portion 131, the suction force acts on the upper side of the cyclone portion 131, and the flow rate of air at the discharge hole 135 is increased. Faster than other parts of the cyclone.

In addition, when the inner upper surface 131a of the cyclone portion 131 is positioned higher than the inner upper surface of the suction guide, part of the air and dust sucked along the suction guide 132 may be disposed in the cyclone portion. Instead of spirally flowing along the inner circumferential surface of 131, the 131 moves upward and is discharged through the discharge hole 135.

However, in the present exemplary embodiment, since the inner upper surface 131a of the cyclone portion 131 and the inner upper surface 132a of the suction guide 132 are positioned on the same horizontal line, they are sucked through the suction guide 132. Air is not moved upwards, it is possible to spiral flow along the inner circumferential surface of the cyclone portion 131 it is possible to smoothly separate the air and dust.

Meanwhile, air and dust introduced into the cyclone part 131 are moved downward while spirally flowing along the inner circumferential surface of the cyclone part 131. In addition, air and dust are separated from each other under different centrifugal forces during the spiral flow.

In addition, air is discharged through the discharge hole 135, and dust separated from the air is moved and stored under the cyclone part 131. Therefore, the inner space of the cyclone unit 131 may be divided into an upper dust separation chamber 133 and a lower first dust storage chamber 134.

The outer circumferential surface of the cyclone portion 131 and the inner circumferential surface of the dust collecting body 110 are spaced apart from each other when the cyclone portion 131 is accommodated in the dust collecting body 110. Therefore, the second dust storage chamber in which the dust discharged through the dust discharge hole 135 of the cyclone portion 131 is stored in the space between the outer circumferential surface of the cyclone portion 131 and the inner circumferential surface of the dust collecting body 110. 120 is formed.

The first dust storage chamber 134 and the second dust storage chamber 120 are simultaneously opened and closed by the lower cover 190.

Therefore, according to the present embodiment, not only dust is stored in the interior of the cyclone portion 131 (first dust storage chamber), but also a space between the cyclone portion 131 and the dust collecting body 110 (first 2 as the dust is stored in the dust storage chamber) there is an advantage that the storage capacity of the dust is increased.

When the lower cover 190 is coupled to the lower side of the dust collecting body 110, the flow preventing rib 198 of the lower cover 190 is located in the second dust storage chamber 120.

The exhaust member 170 is coupled to the inner upper surface 131a of the cyclone portion. When the exhaust member 170 is coupled to the cyclone portion 131, the exhaust guide 144 is positioned inside the exhaust member 170. That is, the exhaust member 170 surrounds the exhaust guide 144.

Meanwhile, referring to FIG. 10, the flow preventing part 180 is coupled to an upper side of the lower cover 190. Therefore, the flow preventing part 180 is rotated together when the lower cover 190 rotates. In addition, when the lower cover 190 is coupled to the dust collecting body 110, the flow preventing part 180 is located in the first dust storage chamber 134, and when the lower cover 190 is rotated. The flow preventing part 180 is withdrawn from the first dust storage chamber 134.

In addition, a part of the blocking part 185 is accommodated in the inner space of the protrusion 142 of the cyclone part 131. Accordingly, the dust dropped into the first dust storage chamber 134 is prevented from being rotated by the support part 184 and the blocking part 185, and dust such as hair is supported by the support part 184 and the blocking part 185. Coiling on is prevented.

As the hair is not wound around the support part 184 and the blocking part 185, the hair and the like can be smoothly discharged to the outside when the lower cover 190 is opened.

The upper surface of the flow preventing part 180 is spaced apart from the bottom of the exhaust member 170 by a predetermined distance. Therefore, the hair or the like that rotates in the circumferential direction of the exhaust member 170 may move toward the first dust storage chamber 134 without being wound around the exhaust member 170.

In addition, as the hair is not wound around the exhaust member 170, the user does not have to remove the hair, and the hair does not block the hole 172 of the exhaust member 170. Can flow smoothly.

Hereinafter, the operation of the dust collecting apparatus will be described.

When the suction force is generated, the air containing dust is introduced into the inner space of the cyclone portion 131 through the suction port 111 and the suction guide 132. Air containing dust introduced into the inner space of the cyclone portion 131 flows spirally along the inner circumferential surface of the cyclone portion 131. In addition, the dust and air flowing along the inner circumferential surface of the cyclone portion 131 are separated from each other while receiving different centrifugal forces due to the weight difference.

After passing through the hole 172 of the exhaust member 170, air (indicated by a solid line) is moved toward the flow path guide 150 through the discharge hole 135 and the through hole 152. The air moved to the flow path guide 150 is filtered while passing through the filter member 250, and the air passing through the filter member 250 passes through the through-hole 235 and the filter case 230. The space between the upper cover 210 is moved.

Thereafter, air moves along the discharge guide part 236 and is discharged to the outside of the dust collecting device 1 through the discharge port 233.

On the other hand, some fine dust (indicated by a dashed-dotted line) separated from the air inside the cyclone portion 131 is moved to the second dust storage chamber 120 through the dust discharge hole 140, and rests. The dust (indicated by a dotted line), such as, etc., is dropped to the lower side of the cyclone part 131 and stored in the first dust storage chamber 130.

On the other hand, in order to empty the dust stored in each of the dust storage chamber (120, 134), the locking action of the hook 194 and the lever 116 is released. Then, the lower cover 190 rotates downward about the hinge 192 to open the respective dust storage chambers 120 and 134 to discharge the dust stored in the dust storage chambers 120 and 134 downward. do.

1 is a perspective view of a dust collecting device according to the present embodiment.

2 is a perspective view of a state in which an upper unit and a lower unit constituting the dust collecting device are separated;

3 is an exploded perspective view of the dust collecting device.

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

5 is a perspective view of the dust separation unit according to the present embodiment.

6 is a plan sectional view of the dust separator of FIG.

7 is a perspective view of a filter case according to the present embodiment.

8 is a perspective view of a flow prevention unit according to the present embodiment.

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

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

FIG. 11 is a cross-sectional view taken along line III-III of FIG. 1; FIG.

Claims (7)

An opening provided to suck air containing dust, and a dust separation unit separating dust from the sucked air; An exhaust guide formed in the dust separation unit for guiding discharge of air from which dust is separated; An exhaust member provided to surround the exhaust guide and filtering air flowing into the exhaust guide; And A dust collecting device of the vacuum cleaner including a guide unit for dividing the exhaust guide so that the air introduced into the exhaust guide is divided and discharged. delete delete The method of claim 1, The exhaust member, the dust collector of the vacuum cleaner is coupled to the inner upper surface of the dust separator. The method of claim 1, The guide part is formed in a plate shape via the center of the exhaust guide, the dust collector of the vacuum cleaner having a height corresponding to the height of the exhaust guide. The method of claim 1, Further comprising a dust collecting body for receiving the dust separation unit, Dust collecting unit of the vacuum cleaner is formed in the dust separation unit is a dust discharge hole for discharging the separated dust to the space between the dust separation unit and the dust collecting body. The method of claim 6, A dust collecting device of the vacuum cleaner, wherein the guide part extends in a direction from the opening toward the dust discharge hole based on a horizontal cross section of the guide part.

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