KR101130033B1 - Dust collecting unit - Google Patents

Abstract

Dust collecting unit according to the present invention is a dust collecting container (300); A partition unit 310 partitioning the dust collecting container 300 into a first dust collecting space 304 and a second dust collecting space 306; A cyclone flow portion 270 which generates a cyclone inside the dust collecting container 300 and has a conical shape at a lower side thereof; And a recess 311 formed at a predetermined interval on an outer surface of the partition portion 310 so that a lower portion of the cyclone flow portion 270 is disposed.

According to the present invention, two cyclone flows are formed to filter foreign matter in the air, and thus, foreign matter in the air is more completely removed.

In addition, there is an advantage that the dust collecting capacity is increased by maximizing the first dust collecting space where the large dust is collected.

Dust collection unit, compartment, depression

Description

Dust collecting unit

1 is a perspective view of a vacuum cleaner according to the present invention.

2 is a perspective view of a dust collecting unit according to the present invention;

3 is an exploded perspective view of the dust collecting unit according to the present invention.

4 is a cutaway perspective view of a dust collecting unit according to the present invention;

5 is a cross-sectional view taken along the line II ′ of FIG. 2.

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

100: dust collecting unit 200: top cover 250: exhaust guide plate

270: cyclone flow portion 300: dust collector 304: first dust collection space

306: second dust collecting space 310: partition portion 311: depression

400: lower cover

The present invention relates to a dust collecting unit of a vacuum cleaner, and more particularly, to a multi-cyclone type dust collecting unit for filtering foreign matter in the air in various stages.

In general, a vacuum cleaner is a device that sucks air containing foreign matters such as dust by using a vacuum pressure generated by a vacuum motor mounted inside the main body, and then filters the foreign matters inside the main 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 connecting pipe, and an upright method in which the nozzle part is integrally formed with the main body.

On the other hand, the dust collecting unit mounted on the cyclone vacuum cleaner uses the cyclone principle to separate and collect the foreign matter contained in the inhaled air and rotate together, and to remove the foreign matter to be discharged to the outside. Device.

The dust collecting unit installed in the conventional cyclone vacuum cleaner includes a cylindrical cyclone body, an air inlet pipe through which air and various foreign substances are sucked, an air discharge hole through which the air introduced into the cyclone body is discharged, and the various foreign substances Includes a filter that filters At this time, the bottom space of the cyclone body is formed in the dust collecting space partitioned by the partition wall, the partition wall is formed with a foreign matter discharge hole for the discharge of foreign matter into the dust collecting space.

The operation of the cyclone dust collecting device having the above configuration will be described briefly. When the suction force generating means is driven, external air containing foreign matter is sucked into the cyclone body. At this time, the air containing the foreign matter is sucked in a tangential direction to the cyclone body through the air inlet pipe of the cyclone body, and then descends while turning along the inner wall surface of the cyclone body. In this process, air and foreign matter are separated from each other under different centrifugal forces by their weight differences. Relatively heavy foreign matter flows down the inner wall surface of the cyclone body while being subjected to centrifugal force and is discharged into the dust collecting space that is the bottom of the cyclone body through the foreign matter discharge hole.

Through this process, fine foreign matters accumulate on the surface of the dust filter. When foreign matters accumulate on the surface of the dust filter, the flow of air is not made smoothly and foreign matters in the air are not smoothly removed. That is, in the prior art as described above, since the filtering is performed by a single dust collecting means, it is difficult to effectively filter the foreign material. Therefore, there is a problem that you need to brush off or clean the foreign matter on the surface of the dust filter.

The present invention has been made to solve the problems described above, and aims to propose a dust collecting unit in which two cyclone flows are formed to filter foreign matter in the air.

Another object of the present invention is to propose a dust collecting unit in which the dust collecting capacity of the first dust collecting space is increased.

Dust collecting unit according to the present invention is a dust collecting container (300); A partition unit 310 partitioning the dust collecting container 300 into a first dust collecting space 304 and a second dust collecting space 306; A cyclone flow portion 270 which generates a cyclone inside the dust collecting container 300 and has a conical shape at a lower side thereof; And a recess 311 formed at a predetermined interval on an outer surface of the partition portion 310 so that a lower portion of the cyclone flow portion 270 is disposed.

Since the foreign matter in the air is filtered in several stages by the dust collecting unit as described above, the performance of the vacuum cleaner is improved, and the dust collecting capacity of the first dust collecting space is maximized to collect more dust.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. 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 implement other embodiments within the scope of the same idea.

1 is a perspective view of a vacuum cleaner according to the present invention.

Referring to FIG. 1, the vacuum cleaner 50 according to the present invention includes a suction nozzle body 60 that sucks air containing foreign substances while moving along a bottom surface, and foreign substances through the suction nozzle body 60. The body 70 has a means for generating a suction force for sucking the air to be installed, the handle portion 80 is installed on the upper portion of the body 70 for the user to grab, and through the suction nozzle body 60 Dust collecting unit 100 that serves to filter foreign matter in the suction air, and the connection hose 90 is formed between the suction nozzle body 60 and the body 70 to guide the flow of air and dirt do.

In detail, the suction nozzle body 60 is a portion for sucking air through a suction port (not shown) formed in the bottom surface thereof while moving in a state close to the bottom surface. That is, a suction port (not shown) is formed on the bottom of the suction nozzle body 60 to serve as a main suction passage of external air, thereby guiding the inflow of air. In addition, the suction nozzle body 60 is generally provided with moving wheels 62 on both sides to facilitate the movement.

The connection part of the suction nozzle body 60 and the body 70 is configured such that the body 70 is rotatable within a predetermined angle range, the suction nozzle body 60 to control the rotation of the body 70 At the rear end of the upper surface, a pivoting lever 64 is formed. Therefore, when the user grasps the handle 80 with his hand and pulls the body 70 backward by using the foot, the body 70 is inclined backward. In this case, the user can clean the bottom surface while adjusting the body 70 to a desired angle according to his height.

In addition, the dust collecting unit 100 filters foreign matter by a cyclone method, and is formed to be detachably attached to the body 70 in a cylindrical shape.

Hereinafter, the operation of the vacuum cleaner 50 will be briefly described.

When power is applied to the vacuum cleaner 50, the suction motor of the vacuum cleaner 50 is operated, and air containing dust or the like is sucked by the vacuum pressure generated by the suction motor. The outside air to be sucked is sucked into the body 70 through the suction nozzle body 60 and the connection hose 90, and the air sucked into the body 70 is introduced into the dust collecting unit 100. In the dust collecting unit 100, dust and the like are filtered by the multi-cyclone method, and the dust and the filtered air are discharged to the outside of the body 70.

Although the upright type vacuum cleaner 50 is shown in FIG. 1, the idea of the present invention may be applied to the canister type vacuum cleaner 50 in addition to the upright type vacuum cleaner 50.

2 is a perspective view of a dust collecting unit according to the present invention.

Referring to FIG. 2, the dust collecting unit 100 according to the present invention includes a dust collecting dust 300 in which dust is collected, an upper cover 200 which shields an upper portion of the dust collecting dust 300, and the dust collecting dust 300. A lower cover 400 is provided to selectively shield the bottom of the cover.

In detail, the dust collecting container 300 has a suction guide 272 through which air is introduced from the outside, a handle 302 for allowing a user to grip, and a hook 320 to be coupled to the lower cover 400. ) Is formed.

In addition, two dust collecting spaces are formed in the dust collecting container 300, and are formed in a predetermined structure to be described below to prevent gaps formed in the two dust collecting spaces.

Meanwhile, the upper cover 200 has a discharge port 210 through which the air filtered by the dust collecting container 300 is discharged, and a latch 220 for allowing the dust collecting unit 100 to be coupled to the body 70. Is formed.

On the other hand, the lower cover 400 has a locking end 410 is formed to be coupled to the locking ring 320, the dust is filtered in the dust collecting container 300 is accumulated.

Hereinafter, the operation or operation of the dust collecting unit 110 will be briefly described. When the air containing the foreign matter is sucked through the suction guide 272, the air containing the foreign matter is filtered through the dual filtering process inside the dust collecting container 300. At this time, the flow of air is blocked between the two dust collecting space by the predetermined structure can improve the separation performance of the dust. After that, the filtered air is discharged through the discharge port 210, and dust is accumulated in two spaces inside the dust collecting container 300.

Hereinafter, the internal structure of the dust collecting unit 100 will be described in detail.

3 is an exploded perspective view of the dust collecting unit according to the present invention.

Referring to FIG. 3, the dust collecting unit 100 according to the present invention includes a dust collecting container 300 through which external air is introduced to filter dust, and an upper cover 200 shielding an upper surface of the dust collecting container 300. The lower cover 400 selectively shields a lower surface of the dust collecting container 300 and accumulates dust.

In addition, an exhaust guide plate 250 is formed below the upper cover 200 to guide filtered air to be discharged, and a cyclone that sucks air from the outside and generates a cyclone under the exhaust guide plate 250. A flow part 270 is formed, and the cyclone flow part 270 is coupled to the filter member 350 that primarily filters the air sucked from the outside.

In detail, the dust collecting container 300 is formed in the compartment 310, the dust is primarily accumulated, and the handle 302 is formed to protrude laterally from the side of the dust collecting container 300 to facilitate the user's gripping And, the engaging ring 320 is coupled to the lower cover 400 is formed.

Here, the partition 310 divides the dust collecting container 300 into two spaces, a first dust collecting space 304 and a second dust collecting space 306. That is, the inner space of the partition 310 becomes the first dust collecting space 304 and the space between the dust collecting container 300 and the partition 310 becomes the second dust collecting space 306.

In addition, the upper outer surface of the partition portion 310 has a shape corresponding to the shape of the cone portion 284 in order to locate a portion of the cone portion 284 formed below the cyclone flow portion 270 which will be described later. A depression 311 is formed, and the partition 310 is formed in a conical shape with a larger diameter toward the lower side, thereby increasing the capacity of the first dust collecting space 304.

On the other hand, the filter member 350 is formed with a filter 352 to primarily filter foreign matter in the air, a plurality of vent holes 354 are formed on the outer peripheral surface of the filter 352. The ventilation hole 354 is to restrict the inflow of large foreign matter and to be able to flow only the fine foreign matter and air to the inside, by the primary cyclone generated along the inner circumferential surface of the cyclone flow portion 270 to be described below Large and heavy foreign material can be filtered.

The foreign material shielding portion 356, which is filtered by the filter 352 in the lower portion of the filter 352 so that foreign matters falling downward are not returned to the upper portion, ie, back to the filter 352 by the rapid flow of air, An airflow interference plate 358 is formed to restrict the scattering of foreign matter by interfering with the airflow generated from the lower portion of the foreign matter shielding portion 356.

When the first cyclone generated around the filter 352 is moved downward along the outer circumferential surface of the filter 352, the airflow interference plate 358 is lower than the foreign matter shielding part 356. Let the first cyclone be offset in.

On the other hand, the cyclone flow unit 270 is formed with a suction guide 272 to allow air to be sucked into the dust collecting unit 100, and a plurality of small cyclone 280 to form a second cyclone. In addition, an inlet 274 through which the air primarily filtered by the filter member 350 is introduced is formed at the center of the cyclone flow unit 270, and the filter member 350 is formed at the inlet 274. Is combined.

In detail, the suction guide 272 penetrates in a tangential direction with respect to the outer circumferential surface of the cyclone flow portion 270. Therefore, when the air is introduced into the cyclone flow portion 270 through the suction guide 272, the air is rotated along the inner circumferential surface to form the first cyclone.

In addition, the small cyclone 280 is composed of a cylindrical portion 282 having a cylindrical shape, and a conical portion 284 having a conical shape formed at the lower end of the cylindrical portion 282. The cylindrical portion 282 and the cone portion 284 are formed integrally with the cyclone flow portion 270 and protrude from the upper and lower portions of the cyclone flow portion 270.

In addition, a plurality of inflow guide pieces 286 are formed at the upper end of the small cyclone 280. The inlet guide piece 286 guides the air introduced through the inlet 274 into the small cyclone 280 and protrudes toward the inlet 274. Therefore, when the air containing the fine foreign matter is exhausted through the inlet 274, the inlet guide piece 286 forms a second cyclone while rotating the air containing the foreign matter along the inner circumferential surface of the small cyclone 280 Done.

On the other hand, the exhaust guide plate 250 is formed on the cyclone flow portion 270. The exhaust guide plate 250 includes a plurality of discharge holes 254 for discharging the air flowing through the cyclone flow part 270, and a lower portion of the discharge hole 254 to provide air to the discharge holes 254. A discharge guide tube 252 is formed to guide the flow of the gas.

In detail, the discharge guide tube 252 has a cylindrical shape and is formed to protrude to a lower side of the discharge hole 254 in a predetermined size. The discharge guide tube 252 is inserted into the cylindrical portion 282 of the small cyclone 280. Therefore, the discharge guide tube 252 allows the filtered air to be discharged through the exhaust guide plate 250.

On the other hand, the top of the exhaust guide plate 250 is provided with an upper cover 200 for shielding the dust collector (300). The upper cover 200 has a latch 220 to be attached to and detached from the body, and a discharge port 210 is formed in the center of the upper cover 200 to discharge the air circulating through the dust collecting container 300. .

An exhaust passage, which is a space of a predetermined size, is formed between the upper cover 200 and the exhaust guide plate 250. Therefore, the air discharged through the discharge hole 254 is discharged to the outside of the dust collecting container 300 through the discharge passage 210 through the exhaust passage.

On the other hand, the lower portion of the dust collecting container 300 is provided with a lower cover 400 for collecting dust to be filtered in the dust collecting container (300). The lower cover 400 is formed with a locking end (not shown) to which the locking ring 320 is coupled, and is hinged to the dust collecting container 300 so as to be rotatable at one side of the dust collecting container 300.

Hereinafter, the shape of the partition 310 will be described in detail.

4 is a cutaway perspective view of a dust collecting unit according to the present invention.

Referring to FIG. 4, in the dust collecting unit 100 according to the present invention, a lower portion of the cyclone flow portion 270 is seated on the upper portion of the partition portion 310.

In detail, a lower portion of the cone portion 284 is seated by a predetermined length on an upper side of the partition portion 310, and the partition portion is disposed so that the cone portion 284 is seated on an upper side of the partition portion 310. A recess 311 having a shape corresponding to that of the cone portion 284, that is, a cone shape is formed at 310.

Here, as the depression 311 is formed, the partition portion 310 is formed to have a larger diameter as it goes down, so that the inner space of the partition portion 310, that is, the first dust collecting space 304 The capacity becomes large, and the outer surface becomes a curved shape as a whole.

In addition, the depression 311 is formed in the same number as the number of the cone portion 284, the diameter is gradually reduced from the upper side to the lower side.

In addition, the depression 311 extends by a predetermined length below the partition 310. As such, the depression 311 extends by a predetermined length, so that the dust flowing through the cone portion 284 is guided by the cone-shaped depression 284 so that the dust can be lowered down well. do.

Hereinafter, an operation or an operation of the dust collecting unit 100 will be described with reference to the above-described configuration.

5 is a cross-sectional view taken along line II ′ of FIG. 2. Referring to FIG. 5, first, power is applied from the outside, and external air and foreign matter introduced through the suction nozzle body 60 are sucked into the dust collecting unit 100 through the suction guide 272. The cyclone is generated by rotating the air and the foreign material sucked through the suction guide 272 along the inner circumferential surface of the cyclone flow unit 270. The cyclone generated inside the cyclone flow part 270 is filtered by the filter 352 and then falls into the first dust collecting space 304.

In detail, the air containing the foreign matter is rotated along the outer circumferential surface of the filter 352, wherein the large and heavy foreign matter is filtered by the vent hole 354 to fall downward, the air containing the fine foreign matter is the vent hole ( It passes through 354 and flows upward through the inlet 274. In addition, the foreign matters dropped into the dust collecting container 300 are restricted from backing upward by the foreign matter shielding unit 356, and the airflow inside the dust collecting container 300 is interfered by the airflow interference plate 358. By doing so, scattering of foreign matter is prevented. Here, the outer surface of the partition 310 is a concave portion 311 is formed so that the overall space of the partition 310 becomes large, a lot of dust can be collected.

Next, the fine foreign matter flowing upward through the inlet 274 is guided by the inlet guide piece 286 and introduced into the small cyclone 280. Air and foreign matter introduced into the small cyclone 280 is lowered in a spiral direction along the inner circumferential surface of the small cyclone 280, and the diameter of the small cyclone 280 is gradually reduced downward The speed of air and foreign matter descending along the inner cyclone 280 gradually increases.

As described above, when air and foreign matter fall along the inner circumferential surface of the small cyclone 280, an upward airflow is formed in the central portion of the small cyclone 280. Therefore, foreign matters in the air flowing in the spiral direction along the inner circumferential surface of the small cyclone 280 are dropped below the small cyclone 280 by inertia and accumulated in the second dust collecting space 306. . At this time, the dust falling into the second dust collecting space 306 is guided by the depression 311 is easily down.

When the foreign matter and air are completely separated through the above process, the purified air is discharged to the outside through the discharge port 210.

According to the present invention, two cyclone flows are formed to filter foreign matter in the air, and thus, foreign matter in the air is more completely removed.

In addition, there is an advantage that the dust collecting capacity is increased by maximizing the first dust collecting space where the large dust is collected.

Claims (5)

Dust collector 300; A partition unit 310 partitioning the dust collecting container 300 into a first dust collecting space 304 and a second dust collecting space 306; A cyclone flow portion 270 which generates a cyclone inside the dust collecting container 300 and has a conical shape at a lower side thereof; And Dust collecting unit including a recessed portion (311) formed at regular intervals on the outer surface of the partition portion 310 so that the lower portion of the cyclone flow portion 270 is disposed. The method of claim 1, Dust collecting unit, characterized in that formed in a shape corresponding to the conical portion (284) of the small cyclone (280) of the cyclone flow portion (270). The method of claim 1, Dust collecting unit, characterized in that the depression 311 is formed to be smaller in diameter toward the lower side. The method of claim 1, The depression unit (311) is a dust collecting unit, characterized in that extending by a predetermined length from the upper side to the lower side of the partition portion (310). The method of claim 1, Dust collecting unit, characterized in that the flow is guided by the depression 311 is introduced into the second dust collecting space (304).

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