KR20090118794A - Cyclone dust collecting apparatus - Google Patents

Abstract

PURPOSE: A cyclone dust collector is provided to minimize pressure loss due to the leakage of the air and simplify the structure by sealing components. CONSTITUTION: A cyclone dust collector comprises a first cyclone part(110), a cyclone unit(100), and a cover unit(200). The first cyclone part has a cyclone chamber for separating the dust from the air flowed in. The cyclone unit is included in the first cyclone part and includes a second cyclone part(130) with a plurality of cones to separate fine dust. The cover unit is installed at the upper part of the cyclone unit and gathers air discharged from the second cyclone part and guides the air to the outside. The first cyclone part has a blocking plate with a plurality of holes connected to a plurality of cones.

Description

Cyclone Dust Collecting Apparatus}

The present invention relates to a cyclone dust collector, and more particularly, to a cyclone dust collector for a vacuum cleaner that separates and collects the dust introduced through the suction port from the air, and discharges the filtered air.

In general, a vacuum cleaner generates a suction force by using a suction motor installed in the cleaner body, and uses the suction force to suck dust or dirt on the surface to be cleaned together with the air using the suction nozzle. The air containing the dirt passes through the cyclone dust collector installed in the cleaner body, and the dirt is removed, and the filtered air is discharged to the outside of the cleaner body.

The conventional cyclone dust collector has a problem that air leaks to the outside due to the poor sealing of the coupling portion between the parts, resulting in a pressure loss in the cyclone dust collector, thereby weakening the suction force There was.

Therefore, there is a problem that the conventional cyclone dust collector has to have a separate sealing device or a sealing member for sealing between these parts, which has a problem that maintenance is not easy because it complicates the configuration of the cyclone dust collector. .

The present invention devised in view of the above problems, by performing the sealing between the components coupled to each other in the cyclone dust collector by itself, the cyclone dust collector that can minimize the pressure loss due to air leakage and simplify the structure The purpose is to provide.

In order to achieve the above object, the present invention includes a primary cyclone portion having a cyclone chamber for separating dust from the introduced air, and the primary cyclone portion in a state separated from the cyclone chamber and separating fine dust A cyclone unit comprising a secondary cyclone portion having a plurality of cones for the; And a cover unit installed at an upper side of the cyclone unit and collecting air discharged from the secondary cyclone unit to guide external discharge, wherein the primary cyclone unit has a plurality of holes communicating with the plurality of cones at a lower portion thereof. Provided is a cyclone dust collector including the formed blocking plate.

The plurality of holes of the blocking plate may include a plurality of protruding pipes protruding into the primary cyclone part to insert the plurality of cone lower parts. In this case, the plurality of cones are sealed through the bottom contact with the protruding tube. In addition, the plurality of cones may include an extension part which is made of a light receiving narrow and is press-inserted into the protruding tube on the outer circumference of the plurality of cones.

Preferably, the primary cyclone part is injection molded integrally with the blocking plate, and the secondary cyclone part is integrally injection molded with a plurality of cones.

The cover unit may include a first cover which is elastically sealed to the secondary cyclone portion through a gasket disposed above the secondary cyclone portion; And a second cover that is face-sealed to each other through surface contact on the first cover, wherein the first cover has a plurality of discharge pipes for discharging air from the plurality of cones of the secondary cyclone part, respectively. And a sealing protrusion formed on a closed curve to include holes of the plurality of discharge pipes on an upper surface of the first cover, wherein the sealing protrusion corresponds to an outline of a space in which air of the second cover is collected. desirable.

In this case, the first cover has a plurality of engaging projections are inserted into the plurality of coupling holes of the second cover, the first and second cover can be fastened by a plurality of screws.

In addition, the cover unit is disposed above the secondary cyclone portion and has a plurality of discharge pipes for discharging air from each of the plurality of cones of the secondary cyclone portion, each of the upper and lower surfaces of the plurality of discharge pipe holes A first cover having a sealing protrusion formed on the closed curve to be formed; And a second cover coupled to an upper side of the first cover, wherein the first cover is sealed in a surface contact state with the secondary cyclone part by a sealing protrusion on a lower surface of the first cover. It is sealed in the surface contact state with the second cover.

The primary cyclone portion may be made of a material at least partially transparent so that the inside can be visually checked.

The present invention may further include a dust collecting unit disposed below the cyclone unit and partitioned into primary and secondary dust collection chambers by partition walls, and the dust collecting unit is dust collected in the primary dust collection chamber. It is preferable that the dust flow inhibiting rib protrudes from the bottom surface to suppress the flow of the gas by the internal airflow.

In the present invention as described above, as a good sealing between the cyclone unit and the cover unit is made, it is possible to prevent the leakage from the cyclone unit in advance, thereby minimizing the pressure loss in the cyclone dust collector, thereby preventing a decrease in suction force.

In addition, the present invention can easily maintain the configuration of the cyclone dust collector by solving the sealing between the parts itself, it is possible to easily maintain.

Hereinafter, the configuration of a cyclone dust collector according to an embodiment of the present invention with reference to the accompanying drawings.

1 to 5, the cyclone dust collector 10 includes a cyclone unit 100, a cover unit 200, and a dust collecting unit 300.

The cyclone unit 100 separates dust introduced with the air from the surface to be cleaned through the suction port (not shown) of the cleaner body (not shown) from the air through centrifugal force. The cyclone unit 100 includes a primary cyclone unit 110 for separating large dust from air and a secondary cyclone unit 130 for separating fine dust from the air filtered by the primary cyclone unit 110. do.

First, the primary cyclone unit 110 includes a body 111 having an open top, and a cyclone chamber 115 partitioned by a separating wall 113 inside the body 111 and a secondary cyclone unit (to be described later) ( An accommodation space 117 is provided for accommodating a plurality of cones 133 of the 130, and the first cyclone unit 110 receives dust and air introduced into the cleaner body (not shown) by an intake body (not shown). Inlet pipe 119 is formed to guide to.

The body 111 is made entirely or partially transparent so that the inside can be visually checked. In addition, the body 111 is a sealing ring (140) is inserted along the lower end (111a), the sealing ring 140 is the airtight between the dust container 300 and the primary cyclone portion 110 By maintaining it, it is possible to prevent the pressure inside the primary cyclone part 110 from being lowered and to prevent dust from leaking out of the cyclone dust collector 10. Furthermore, the body 111 closes the lower portion of the accommodation space 117 to block the fine dust collected in the secondary dust collection chamber 350 of the dust container 300 from entering the accommodation space 117. 112 is integrally injection molded, and the blocking plate 112 has a plurality of protruding tubes 112a protruding into the receiving space 117. The plurality of protruding pipes 112a have the same low height, and the lower portions of the plurality of cones 133 to be described later are tightly inserted, and further, fine dust falling apart from the air from the plurality of cones 133 and falling down is secondary. The second dust collection chamber 350 communicates with the dust collection chamber 350 to be collected.

The cyclone chamber 115 is disposed eccentrically to one side in the interior of the body 111, the receiving space 117 is formed along the periphery of one side of the separation wall (113). In addition, a grill filter 116 is disposed inside the cyclone chamber 115 to prevent large dust separated from air by the centrifugal force from entering the secondary cyclone unit 130.

The grill filter 116 is detachably installed in the inlet hole 131 of the secondary cyclone part 130 by passing through an air discharge hole 113a formed at an upper side of the separation wall 113. In addition, a skirt 116b protrudes along the outer periphery of the grill filter 116, and the skirt 116b is separated from the air in the cyclone chamber 115 and dropped to the dust container 300 to collect the cyclone. It is prevented from flying back into the cyclone chamber 115 by being scattered by the airflow in the chamber 115. In addition, the grill filter 116 is bored with a plurality of grill holes 116c into which the large dust and air separated from the cyclone chamber 115 are introduced.

The secondary cyclone unit 130 includes an inlet hole 131 on which one side of the primary filtered air discharged from the outlet hole 113a of the primary cyclone unit 110 flows. In addition, the secondary cyclone unit 130 has a plurality of cones 133 accommodated in the receiving space 117 of the primary cyclone unit 110 on the other side is arranged in the longitudinal direction of the cyclone dust collector (10). In this case, the secondary cyclone unit 130 is a plurality of inlet holes 131 and a plurality of cones 133 to guide the air introduced from the inlet hole 131 to the inlet 133a of each cone 133 The guide channel 132 is formed. The plurality of guide channels 132 are in tangential communication with the inlets 133a of the plurality of cones 133. Accordingly, the air flowing into the inlets 133a is provided with a plurality of cones in a predetermined turning force. 133) As it turns inside, it is separated from the fine dust by centrifugal force.

The plurality of cones 133 are disposed in the upper and lower straits so as to be inclined from the upper side to the lower side, and the lower portion 133b is formed with an extension part 134 extending vertically along the outer circumference. The extension part 134 is an extension part in the inner circumference of the plurality of protruding pipes 112a when the plurality of cones 133 lower parts 133b are pressed into the plurality of protruding pipes 112a of the blocking plate 112. The outer peripheries of 134 are sealed in surface contact with each other. Sealing due to surface contact between the extension part 134 and the protruding pipe 112a is accommodated through the gap between the extension part 134 and the protruding pipe 112a by the blocking plate 112. Inflow into the space 117 may be prevented at the source. In this regard, as the receiving space 117 is isolated from the plurality of cones 133 so as not to affect the exhaust air flow of the air formed in the plurality of cones 133, pressure loss inside the cyclone unit 100 is reduced. It can be reduced to prevent a decrease in suction power.

The cover unit 200 is installed on the cyclone unit 100 and includes a first cover 210, a second cover 230, and an outer cover 250.

The first cover 210 closes the upper portion of the secondary cyclone portion 130. In this case, as the gasket 400 is installed between the secondary cyclone portion 130 and the first cover 210, the secondary cyclone is disposed. The airtightness is maintained between the upper portion 130 and the first cover 210. In addition, the first cover 210 includes a plurality of discharge pipes 211 respectively corresponding to the plurality of cones 133 of the secondary cyclone part 130. The plurality of discharge pipes 211 penetrate through the plurality of insertion holes 410 formed in the gasket 400 and are disposed coaxially with the plurality of cones 133 on the plurality of cones 133. In addition, the first cover 210 is provided with a sealing protrusion 213 protruding from the upper surface of the first cover 210 to maintain the airtight with the second cover 230. The sealing protrusion 213 is formed on the closed curve to include the upper portion (211a) of the plurality of discharge pipe (211).

The second cover 230 is coupled to an upper side of the first cover 210, and an outer wall 231 is formed to form a confluence chamber 235 where air discharged from the discharge pipe 211 of the first cover 210 collects. . In this case, the outline of the confluence chamber 235 corresponds to the closed curve of the sealing protrusion 213 of the first cover 210, so that the outer circumferential surface 213a of the sealing protrusion 213 when the first and second covers 210 and 230 are coupled to each other. The inner circumferential surface 231a of the outer wall 231 is sealingly coupled in a surface contact state.

In addition, the second cover 230 includes a discharge pipe 233 for discharging the air collected in the confluence chamber 231 to the outside of the dust collector 10. The discharge pipe 233 communicates with a part of the cleaner body so as to communicate with a suction motor (not shown) installed in the cleaner body (not shown).

The outer cover 250 is disposed above the second cover 230 to protect the second cover 230.

The cover unit 200 and the gasket 400 are sequentially coupled to the upper side of the cyclone unit 100. That is, referring to FIGS. 1 and 2, a plurality of coupling protrusions 136 formed on the upper surface of the secondary cyclone part 130 are formed on the gasket 400, the first cover 210, and the second cover 230. The first coupling is achieved by being coupled to the plurality of coupling holes 416; 216; 236, and the plurality of screws 500 are the outer cover 250, the second cover 230, the first cover 210 and the secondary. Secondary coupling is achieved by sequentially passing through a plurality of fastening holes 257; 237; 217; 137 formed in the cyclone part 130 and being fastened to the plurality of screw grooves 118 of the primary cyclone part 110.

As described above, the primary and secondary cyclone portions 110 and 130 are faced to each other by surface contact between the extension portion 134 and the protruding pipe 112a, and the secondary cyclone portion 130 and the first The gasket 410 is elastically sealed between the covers 210, and the first and second covers 210 have an outer circumferential surface 213a of the sealing protrusion 213 and an inner circumferential surface 231a of the outer wall 231. Sealed in contact. As such, the cyclone unit 100 and the cover unit 200 in which the air flow path is formed are sealed in various stages between components to prevent the leakage of air, thereby reducing the pressure loss to a minimum, as well as the cyclone unit 100. The fall of the suction power of a vacuum cleaner can be prevented.

Meanwhile, in the present embodiment, a structure in which the gasket 400 is elastically sealed by placing the gasket 400 between the secondary cyclone part 130 and the first cover 210 has been described. However, the present invention is not limited thereto, and the gasket 400 is omitted. Sealing between the secondary cyclone portion 130 and the first cover 210 is possible. That is, as shown in Figure 6, the bottom of the first cover 210 to form another sealing projection 215 on the closed vessel including a plurality of discharge pipe 211. The sealing protrusion 215 corresponds to an outline formed by a plurality of guide channels 132, the inlet hole 131 of the secondary cyclone part 130, and the space adjacent to the inlet hole 133a of the cone 133. Accordingly, when the first cover 230 is coupled to the upper side of the second cyclone unit 130, the outer circumferential surface 215a of the sealing protrusion 215 forms the outline of the space and the inner circumferential surface 130a of the secondary cyclone unit 130. Sealing is combined with the surface contact state. Accordingly, the airtightness between the secondary cyclone part 130 and the first cover 210 may be maintained through surface sealing.

The dust collection unit 300 is disposed below the cyclone unit 100 and partitioned into the primary and secondary dust collection chambers 330 and 350 by the partition 310. The primary dust collection chamber 330 is set at a position corresponding to the cyclone chamber 115 to collect the large dust separated by the primary cyclone unit 110, and the secondary dust collection chamber 350 is the secondary cyclone It is set at a position corresponding to the accommodation space 117 in which the plurality of cones 133 are accommodated to collect the fine dust separated by the unit 130.

In addition, the dust collection unit 300 is a plurality of protruding from the bottom surface of the dust collection unit 300 to prevent the dust collected from the primary cyclone unit 110 flow by the internal air flow of the primary collection chamber 330 Dust flow suppressing rib 390 is provided.

Referring to the operation of the cyclone dust collector according to an embodiment of the present invention configured as described above are as follows.

First, the suction motor (not shown) of the cleaner body (not shown) is operated, and the suction port (not shown) is seated on the surface to be cleaned to introduce dust and air into the cleaner body.

The dust and air introduced in this way is introduced into the inlet pipe 119 of the cyclone unit 100 along the cleaner body (not shown).

Referring to FIG. 5, dust and air introduced into the cyclone chamber 115 of the primary cyclone unit 110 through the inlet pipe 119 are swiveled in the cyclone chamber 115, and in this case, the centrifugal force causes a large amount. The dust is separated from the air and descends while turning along the inner wall of the separation wall 113. Accordingly, the large dust is collected by the primary dust collection chamber 330, and the air separated from the large dust is introduced into the grill filter 116 through the grill hole 116c of the grill filter 116.

As such, the air introduced into the grill filter 116 continues to flow into the secondary cyclone unit 130 through the inlet hole 131. Air is then introduced into the plurality of cones 133 along the plurality of guide channels 132, respectively, and then rotates inside the plurality of cones 133 with a predetermined turning force. Accordingly, after the fine dust is separated from the air by centrifugal force, the fine dust is collected and dropped into the secondary dust collection chamber 350 of the dust container 300, and the air separated from the fine dust is respectively discharged through a plurality of discharge pipes 211. Is discharged from the cone 133 to the confluence chamber 231 of the second cover 230.

The air discharged to the confluence chamber 231 is discharged to the outside of the dust collector 10 through the discharge pipe 233, and then moves along the cleaner body (not shown) and passes through the suction motor (not shown) to the cleaner body (not shown). ) It is discharged to the outside.

1 is a perspective view showing a cyclone dust collector according to an embodiment of the present invention in a state separated from the cleaner body,

Figure 2 is a perspective view showing the rear of the cyclone dust collector according to an embodiment of the present invention,

3 is an exploded perspective view of a cyclone dust collector according to an embodiment of the present invention;

4 is a plan view of a cyclone dust collector according to an embodiment of the present invention,

5 is a cross-sectional view taken along the line VV of FIG. 4;

6 is a perspective view illustrating another embodiment of the first cover illustrated in FIG. 3;

FIG. 7 is a perspective view illustrating a dust flow inhibiting rib inside the dust collecting unit illustrated in FIG. 2.

* Description of Signs for Main Parts in Drawings *

100: cyclone unit 110: primary cyclone portion

112: blocking plate 112a: protruding pipe

130: secondary cyclone portion 200: cover unit

210: first cover 213, 215: sealing protrusion

230: second cover 400: gasket

Claims (13)

A primary cyclone portion having a cyclone chamber for separating dust from the introduced air, and a secondary cyclone portion included in the primary cyclone portion in isolation from the cyclone chamber and having a plurality of cones for separating fine dust. A cyclone unit comprising; And, And a cover unit installed at an upper side of the cyclone unit to collect air discharged from the secondary cyclone unit to guide external discharge. And the primary cyclone part includes a blocking plate having a plurality of holes formed therein in communication with the plurality of cones. The cyclone dust collecting apparatus of claim 1, wherein the plurality of holes of the blocking plate include a plurality of protruding tubes protruding into the primary cyclone portion and into which the plurality of cone lower parts are inserted. The cyclone dust collector of claim 2, wherein the plurality of cones have a lower portion sealed through surface contact with the protruding tube. The cyclone dust collector of claim 3, wherein the plurality of cones comprise an extension portion which is made of a light receiving narrow and is press-inserted into the protruding tube on the outer circumference of the plurality of cones. The cyclone dust collector of claim 1, wherein the primary cyclone part is injection molded integrally with the blocking plate. The cyclone dust collector of claim 1, wherein the secondary cyclone part is integrally formed by injection of a plurality of cones. According to any one of claims 1 to 3, wherein the cover unit A first cover which is elastically sealed to the secondary cyclone portion through a gasket disposed above the secondary cyclone portion; And, And a second cover which is mutually face-sealed through surface contact on the first cover. The method of claim 7, wherein the first cover has a plurality of discharge pipes for discharging air from each of the plurality of cones of the secondary cyclone portion, the upper surface of the first cover closed curve to include the holes of the plurality of discharge pipes And a sealing protrusion made of a phase, wherein the sealing protrusion is formed to correspond to an outline of a space in which air of the second cover is collected. The cyclone according to claim 7, wherein the first cover has a plurality of coupling protrusions inserted into a plurality of coupling holes of the second cover, and the first and second covers are fastened by a plurality of screws. Dust collector. According to any one of claims 1 to 3, wherein the cover unit It is disposed above the secondary cyclone portion and has a plurality of discharge pipes for discharging air from the plurality of cones of the secondary cyclone portion, respectively, and formed on a closed curve so as to include the holes of the plurality of discharge pipes on the upper and lower surfaces, respectively. A first cover in which a sealing protrusion is formed; And, And a second cover coupled to the upper side of the first cover. The first cover is sealed in mutual contact with the secondary cyclone portion by a sealing protrusion on the lower surface, and the cyclone dust collector is sealed in mutual contact with the second cover by the sealing protrusion on the upper surface. . The cyclone according to claim 10, wherein the first cover has a plurality of coupling protrusions inserted into the plurality of coupling holes of the second cover, and the first and second covers are fastened by a plurality of screws. Dust collector. The cyclone dust collector of claim 1, wherein at least a portion of the primary cyclone part is made of a transparent material. The dust collecting apparatus of claim 1, further comprising a dust collecting unit disposed below the cyclone unit and partitioned into primary and secondary dust collection chambers by a partition wall, And the dust collecting unit protrudes from the bottom surface of the dust flow inhibiting rib for preventing the dust collected in the primary dust collection chamber from flowing by internal airflow.

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