KR101174915B1 - A dust collecting body structure of a vaccum cleaner - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum cleaner, and more particularly, to a dust collecting body structure of a vacuum cleaner in which a space in which a foreign material is stored is enlarged and dust collection performance is improved.

The dust collecting body structure of the vacuum cleaner according to the present invention includes: a first dust collecting unit configured to collect foreign materials by primary cyclone flow; A plurality of small cyclone portions through which the air passing through the first dust collector is introduced to form a secondary cyclone flow; A second dust collecting unit configured to collect the foreign matter by the secondary cyclone flow; A third dust collecting part provided outside the second dust collecting part to introduce a part of air introduced into the first dust collecting part; And at least one vent hole formed on the outer circumferential surface of the small cyclone portion, and includes a foreign material collecting space in which a relatively large foreign material can be collected by the present invention, and a relatively large foreign material is divided into two parts. By doing so, there is an advantage that the foreign matter separation performance in each dust collecting unit is improved.

Vacuum cleaner, dust collecting body

Description

A dust collecting body structure of a vaccum cleaner

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

Figure 2 is a perspective view showing a state in which the dust collecting unit is separated from the main body of the vacuum cleaner according to the present invention.

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

4 is a view showing the internal configuration of the dust collecting body according to the present invention.

5 is a bottom perspective view of the exhaust guide according to the present invention;

6 is a sectional view of a dust collecting unit according to the present invention;

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

100: main body 200: dust collection unit

250: dust collecting body 256: guide hole

257: air outlet hole 258: air vent

The present invention relates to a vacuum cleaner, and more particularly, to a dust collecting body structure of a vacuum cleaner in which a space in which foreign materials are stored is enlarged and dust collection performance is improved.

In general, a vacuum cleaner is a home appliance that cleans an indoor environment by external air being forcibly sucked by a suction force generated by a motor, and foreign matter contained in the sucked air is filtered by a predetermined filtering member.

On the other hand, the filtering mechanism for filtering foreign matter from the dust collecting unit of the vacuum cleaner includes a porous filter unit forcibly filtering foreign matter while passing through the porous filter, and a cyclone method for filtering foreign matter by centrifugal force during the cyclone flow of air. There is a dust collection unit. In recent years, cyclone dust collecting units that can be used semi-permanently without replacement are being widely used.

In addition, the cyclone dust collection unit is provided with a foreign matter separation chamber in which a cyclone air flow is formed to separate foreign matter, and a foreign matter storage chamber in which foreign matter separated from the foreign matter separation chamber is stored. The foreign matter storage chamber is divided into a first foreign matter storage chamber in which relatively large foreign matter is stored, and a second foreign matter storage chamber in which fine dust is stored. With this structure, foreign matter separated from the foreign matter separation chamber is continuously accumulated in the foreign matter storage chamber.

By the way, the foreign matter collected in the foreign matter storage chamber, if not discarded in a proper time, there is a problem that the dust collection efficiency of the cleaner is lowered, and the appearance is not good even if it is not discarded in a proper time. Substantially accumulated foreign matter inside the foreign matter storage chamber is small in volume but excessively large, there is a disadvantage in use that the user frequently has to empty the foreign matter storage chamber. In particular, in the case of a foreign substance storage chamber in which a relatively large foreign substance is stored, the frequency of emptying the foreign substance storage chamber becomes large.

The present invention has been proposed to solve the above problems, and an object of the present invention is to propose a dust collecting body structure of a vacuum cleaner in which a space for storing a relatively large foreign material is enlarged, thereby improving foreign matter separating performance.

In addition, by increasing the amount of foreign matter that can be collected inside the dust collector of the same volume, the purpose of suggesting a dust collecting body structure of the vacuum cleaner that can be used more conveniently by reducing the cycle of the user discards the foreign material do.

The dust collecting body structure of the vacuum cleaner according to the present invention for achieving the object as described above comprises a first dust collecting unit for collecting the foreign matter by the primary cyclone flow; A plurality of small cyclone portions through which the air passing through the first dust collector is introduced to form a secondary cyclone flow; A second dust collecting unit configured to collect the foreign matter by the secondary cyclone flow; A third dust collecting part provided outside the second dust collecting part to introduce a part of air introduced into the first dust collecting part; And at least one vent formed on an outer circumferential surface of the small cyclone portion.

The present invention as described above is provided with a dust collecting unit that can collect a relatively large foreign matter on the outside of the dust collecting body, there is an effect that the foreign matter collecting space is expanded.

In addition, by separating the relatively large foreign matter divided in two places, there is an effect that the foreign matter separation performance in each dust collector is improved. That is, as some of the incoming air and foreign matter is introduced in two places, the amount of air and foreign matter present in each dust collection unit is relatively reduced, and the separation performance is improved.

In addition, the stacking density of the foreign material to be collected is increased, the amount of the foreign material that can be collected is increased, the frequency of discarding the foreign material by the user is reduced, there is an effect that the user's convenience is enhanced.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

1 is an external perspective view of a vacuum cleaner according to the present invention, Figure 2 is a perspective view showing a state in which the dust collecting unit is separated from the main body of the vacuum cleaner according to the present invention.

1 and 2, the vacuum cleaner according to the present invention includes a main body 100 and a suction pipe path 50 connected to the suction side of the main body. In addition, at least a motor (not shown) and a dust collecting unit 200 are disposed inside the main body 100 so that foreign matter is filtered out and cleaned in the sucked air and then discharged to the outside.

In detail, the suction pipe path 50 is a pipe path through which foreign substances are sucked together with air by the suction force of the main body 100. In addition, the suction pipe path 50 extends from the suction nozzle body 10 and the suction nozzle body 10 to allow the air containing foreign matters to be sucked from the outside by a strong air flow, and according to a user's use state. Extension tube 20 is adjustable in length, and the handle 30 is provided at the end of the extension tube 20 to facilitate the user's grip. In addition, an operation unit 34 is provided at a portion where the user's hand touches the front of the handle 30.

In addition, the suction pipe passage 50 further extends rearward from the handle 30 and is flexible to be movable according to the position of the user, and a connector connected to the main body at the end of the flexible hose 40. 44 and an extension tube hanger 60 for positioning the extension tube 20 or the suction nozzle body 10 so that the extension tube 20 can be mounted when the vacuum cleaner is not used.

In detail, the connector 44 has a function of a connecting terminal for allowing a user's operation signal input from the operation unit 34 to be applied to the main body 100, and allows suctioned air to flow into the main body 100. The function is performed at the same time. To this end, a plurality of electrical connection ends (not shown) are further provided at the ends of the connector 44.

On the other hand, the main body 100 is configured such that the dust collecting unit 200 is seated in the vertical direction. In addition, a dust collecting unit accommodating part 130 for accommodating the dust collecting unit 200 is formed in the main body 100 in a shape corresponding to the dust collecting unit 200.

In addition, the dust collecting unit 200 functions to separate and collect the foreign matter from the air containing the foreign matter introduced through the suction pipe passage 50. In addition, the air discharged from the dust collecting unit 200 is discharged to the rear of the main body 100 through a predetermined flow path and the motor formed inside the main body 100.

In addition, the upper portion of the front end of the main body 100 is provided with a connecting portion 110 to which the connector 44 is connected, so that the main body 100 can smoothly move the bottom surface on both rear sides of the main body 100. Each wheel 120 is rotatably mounted.

Hereinafter, the configuration of the dust collecting unit 200 will be described in detail.

Figure 3 is an exploded perspective view of the dust collecting unit according to the present invention, Figure 4 is a view showing the internal configuration of the dust collecting body according to the present invention, Figure 5 is a bottom perspective view of the exhaust guide according to the present invention.

3 to 5, the dust collecting unit 200 according to the present invention does not use a porous filter such as a sponge, and the like to filter foreign matter in the cyclone flow. The cyclone flow is performed in two or more separation chambers separated from each other, so that fine dust in the air is completely filtered.

In detail, the dust collecting unit 100 according to the present invention includes a dust collecting body 250 into which air containing foreign matter is introduced and foreign matters are filtered, an upper cover 210 which shields an upper portion of the dust collecting body 250. A lower cover 230 for selectively shielding the lower part of the dust collecting body 250 is included.

In addition, the lower side of the upper cover 210 is provided with an exhaust guide portion 220 for guiding the filtered air is discharged, the central portion of the dust collecting body 250, the filter for primarily filtering the air sucked from the outside Member 290 is coupled.

In more detail, the dust collecting body 250 is provided with a plurality of walls extending vertically, the inner wall 262 is formed on the innermost side, the intermediate wall 264 formed on the outer side of the inner wall 262, and An outer wall 266 formed outside the intermediate wall 264 and an auxiliary wall 268 extending from the outer wall 266 are included.

In addition, a first dust collecting part 272 is formed in an inner space of the inner wall 262 and an inner space of the intermediate wall 264, and a second dust collecting part is disposed between the intermediate wall 264 and the outer wall 266. 274 is formed, and a third dust collecting part 276 is formed between the predetermined portion of the outer wall 266 and the auxiliary wall 268. That is, three dust collecting parts 272, 274, 276 are formed in the dust collecting body 250 according to the exemplary embodiment of the present invention.

In addition, the first dust collecting part 272 is a space in which a relatively large foreign material is collected by the first cyclone flow among the cyclone flow generated inside the dust collecting body 250, and the second dust collecting part 274 is a second dust collecting part 274. It is a space where fine foreign matter is collected by cyclone flow. In addition, the third dust collecting unit 276 is a space in which foreign matter introduced from the first dust collecting unit 272 is collected. Here, the number and purpose of use of the dust collecting part is found to vary depending on the shape of the dust collecting body (250).

In addition, a suction guide 252 is formed on one side of the dust collecting body 250 to suck the air introduced from the outside. In detail, the suction guide 252 is connected to the inner wall 262 and penetrates to lie in a tangential direction with respect to the outer circumferential surface of the inner wall 262. Therefore, when air is introduced into the dust collecting body 250 through the suction guide 252, the introduced air is rotated along the inner circumferential surface of the inner wall 262 to form a first cyclone flow. Then, the foreign matter is separable by the first cyclone flow.

In addition, a guide hole 256 is formed at a position opposite to the suction guide 252 so that a part of the air introduced into the first dust collecting part 272 flows into the third dust collecting part 276. The guide hole 256 is formed through the inner wall 262, the middle wall 264, and the outer wall 266, so that some air introduced into the first dust collecting part 272 passes through the third dust collecting part 276. Guide to flow into. That is, some of the air flowing into the suction guide 252 is rotated in the first dust collecting part 272 while flowing along the inner wall 262, the other part flows in a straight line to the third dust collecting part 276 Flows within.

Here, the guide hole 256 is not limited in shape, and preferably formed in a shape in which air and foreign matter can easily flow into the third dust collecting part 276.

In addition, the air introduced into the third dust collecting part 276 is discharged through the air discharge hole 257. In detail, the air discharge hole 257 is formed through the outer wall 266 and the intermediate wall 264 to allow air discharged from the third dust collecting part 276 to flow into the first dust collecting part 272. Here, a plurality of air discharge holes 257 may be formed according to the size of the third dust collecting part 276.

Therefore, the air introduced into the third dust collecting part 276 by the air discharge hole 257 can be discharged, thereby preventing the backflow of air and foreign matter into the guide hole 256. In addition, the air discharge hole 257 is preferably formed inside the third dust collecting part 276 such that foreign matter is sequentially collected from the inside in the third dust collecting part 276.

The air discharge hole 257 is formed below the third dust collecting part 276 so that the discharged air flows in from the lower side of the first dust collecting part 272. Therefore, it is possible to restrict the scattering of foreign matter collected in the first dust collector 272 by interfering with the air flow generated from the lower side of the first dust collector 272.

In addition, a plurality of vent holes 258 through which a part of the air of the third dust collecting part 276 is discharged is formed above the air discharge hole 257. Here, the vent 258 is formed through the small cyclone portion 280 to be described later. In addition, the vent hole 258 is not formed in all of the small cyclone portions 280, so that foreign matter is sequentially collected from the inside of the third dust collecting portion 276, that is, the air discharge hole 257. It is formed in the small cyclone portion 280 located above. Therefore, a small amount of air discharged into the vent hole 258 is introduced into the small cyclone portion 280. That is, in the process of discharging the air introduced into the third dust collecting part 276 through the air discharge hole 257, the air remaining on the upper side of the small cyclone part 280 passes through the vent hole 258. It is flowing inside.

The vent 258 is provided with a network 259 for filtering fine dust. The net 259 may be provided inside the ventilation hole 258 or may be provided on an inner circumferential surface or an outer circumferential surface of the small cyclone portion 280.

Therefore, a small amount of air is discharged through the vent hole 259 to prevent the scattering of foreign matters and to stack the inside of the third dust collecting part 276 gradually. That is, a large amount of foreign matter can be collected in the same volume.

Here, the guide hole 256, the air discharge hole 257 and the vent 258 can be clearly understood through FIG.

As described above, since the third dust collecting part 276 may collect a relatively large foreign material, there is an advantage that the foreign matter storage space is enlarged.

In addition, by collecting the foreign matter in two places, the separation performance of the foreign matter in the dust collector is improved. That is, as a portion of the air and foreign matter introduced into the third dust collecting part 276, the amount of air and foreign matter present in the first dust collecting part 272 is relatively reduced, the first dust collecting part 272 Cyclone flow in can be made smoothly. In addition, the third dust collecting part 276 is not affected by the cyclone flow, thereby reducing the scattering of foreign matter, and the foreign matter is sequentially stored from the inside, so that the foreign matter storage space is efficiently used.

On the other hand, a plurality of small cyclone portion 280 to form a second cyclone flow is formed in the upper portion of the dust collecting body 250, the inlet for the air flowing through the first dust collecting portion 272 in the central portion 254 is formed, and the inlet 254 is coupled to the filter member 290 that primarily filters the air introduced into the first dust collector 272.

In detail, the small cyclone portion 280 includes a cylindrical portion 282 having a cylindrical shape, and a conical portion 284 extending from a lower end of the cylindrical portion 282 and having a conical shape. That is, the small cyclone portion 280 is smaller in diameter toward the lower side. In addition, the cylindrical portion 282 protrudes upward of the dust collecting body 250, and the conical portion 284 protrudes into the dust collecting body 250. Here, the cone 284 is integrally formed with the intermediate wall 264. Accordingly, the fine foreign matter separated by the second cyclone flow easily flows down the intermediate wall 264.

In addition, as the intermediate wall 264 is integrally formed with the cone portion 284, the intermediate wall 264 has bent portions 265 formed at predetermined curvatures at regular intervals. Therefore, the airflow generated by the air introduced into the second dust collecting part 274 by the bent portion 265 interferes with the scattering of foreign matters, and the flow of the foreign matters is guided.

In addition, the filter member 290 is formed in a conical shape so that foreign matter separation is smoothly performed in the cyclone flow. In addition, a plurality of through holes 292 are formed on an outer circumferential surface of the filter member 290. The through hole 292 restricts the inflow of large foreign matter and allows only fine foreign matter and air to flow therein.

On the other hand, the exhaust guide portion 220 is mounted on the dust collecting body 250. In addition, a plurality of discharge holes 222 for discharging air flowing through the small cyclone part 280 is discharged to the upper surface of the exhaust guide part 220, and guides the flow of air to the discharge holes 222. The discharge guide tube 224 is formed. In addition, a plurality of engaging protrusions 226 are formed on the outer circumferential surface of the exhaust guide part 220 to be coupled to the upper cover 210.

In detail, the discharge guide tube 224 has a cylindrical shape and is formed to protrude downward from the discharge hole 222. The discharge guide tubes 224 are respectively inserted into the cylindrical portions 282 of the small cyclone portion 280. Accordingly, the discharge guide tube 224 allows the filtered air to be discharged through the exhaust guide part 220.

In addition, the upper cover 210 of the lower end is detachably coupled to the upper side of the exhaust guide portion 220. In addition, the upper portion of the upper cover 210 is provided with a handle 212 to enable the user to grip.

Accordingly, the user can easily attach and detach the dust collecting unit 200 to the main body 100 while holding the handle 212. A discharge port (see 214 of FIG. 6) through which the air flowing through the dust collecting unit 200 is discharged to the outside of the dust collecting unit 200 is formed at a rear portion of the upper cover 210.

On the other hand, the lower cover 230, which forms the bottom of the dust collecting portion 272, 274, 276 is hinged to the lower portion of the dust collecting body 250. The lower cover 230 simultaneously seals the plurality of dust collectors 272, 274 and 276, and provides a sealer to prevent foreign substances stored in the dust collectors 272, 274 and 276 from leaking. Can be.

Hereinafter, with reference to the configuration described above, the operation of the dust collecting unit 200 will be described.

6 is a sectional view of a dust collecting unit according to the present invention. Referring to FIG. 6, when power is first applied to the vacuum cleaner 100, suction power is generated by a motor built in the main body 100, and air containing foreign matter is sucked through the suction nozzle body 10. . In addition, the sucked air is sucked into the dust collecting unit 200 through the suction guide 252.

In detail, the air sucked through the suction guide 252 is first introduced into the first dust collecting part 272. At this time, some of the incoming air rotates along the inner circumferential surface of the inner wall 262, thereby generating a first cyclone flow. The other part flows into the third dust collecting part 276 through the guide hole 256.

During the cyclone flow of air inside the first dust collector 272, foreign matter is filtered by the filter 292 and then falls below the first dust collector 272, and clean air is filtered. It passes through the through hole 292 of 290 is discharged upward through the inlet 254. In addition, the air introduced into the third dust collecting part 276 passes through the air discharge hole 257 and is discharged into the first dust collecting part 272. At this time, some of the air of the third dust collecting part 276 is introduced into the small cyclone portion 280 through the vent hole 258.

Therefore, the foreign matter is sequentially collected from the inside of the third dust collecting part 276, the stacking density of the collected foreign material is increased, a large amount of foreign matter may be collected in the third dust collecting part 276. Here, the air discharged to the first dust collector 272 through the air discharge hole 257 interferes with the airflow generated from the lower side of the first dust collector 272, foreign matter inside the first dust collector 272 Scattering is regulated.

In addition, as a relatively large foreign material is divided into the first dust collecting part 272 and the third dust collecting part 276, the separation performance of the foreign material in the dust collecting parts 272 and 276, respectively, as described above.

Then, the fine foreign matter flowing upward through the inlet 254 is introduced into the small cyclone portion 280. In addition, air and foreign matter introduced into the small cyclone portion 280 are lowered in a spiral direction along an inner circumferential surface of the small cyclone portion 280. At this time, since the diameter of the small cyclone portion 280 gradually decreases downward, the speed of air and foreign matter descending along the inner circumferential surface of the small cyclone portion 280 is gradually increased.

In addition, when air and foreign matter fall along the inner circumferential surface of the small cyclone portion 280, an upward airflow is formed at the central portion of the small cyclone portion 280. Therefore, foreign matters in the air flowing in the spiral direction along the inner circumferential surface of the small cyclone portion 280 are dropped below the small cyclone portion 280 by inertia and accumulated in the second dust collector 274. . At this time, the dust falling to the second dust collecting part 274 is guided by the bent portion 265 is easily dropped downward.

When the foreign matter and the air are completely separated through the above process, the purified air flows upward through the discharge guide tube 224 to be introduced into the upper cover 210.

Then, the air introduced into the upper cover 210 is discharged backward through the discharge port 214, the air discharged from the discharge port 214 flows along a predetermined path inside the main body 100 after It is discharged to the outside of the main body 100.

According to the present invention, a dust collecting part capable of collecting a relatively large foreign material is provided on the outer side of the dust collecting body, so that the foreign material collecting space is expanded.

In addition, by separating the relatively large foreign matter divided in two places, there is an effect that the foreign matter separation performance in each dust collector is improved. That is, as some of the incoming air and foreign matter is introduced in two places, the amount of air and foreign matter present in each dust collection unit is relatively reduced, and the separation performance is improved.

In addition, the stacking density of the foreign material to be collected is increased, the amount of the foreign material that can be collected is increased, the frequency of discarding the foreign material by the user is reduced, there is an effect that the user's convenience is enhanced.

Claims (7)

A first dust collecting part configured to collect the foreign matter by the primary cyclone flow; A plurality of small cyclone portions through which the air passing through the first dust collector is introduced to form a secondary cyclone flow; A second dust collecting unit configured to collect the foreign matter by the secondary cyclone flow; A third dust collecting part provided outside the second dust collecting part to introduce a part of air introduced into the first dust collecting part; And Dust collecting body structure of a vacuum cleaner that includes; at least one vent formed on the outer circumferential surface of the small cyclone portion. The method of claim 1, A dust collecting body structure of a vacuum cleaner in which a guide hole is formed so that a part of the air introduced into the first dust collecting part flows into the third dust collecting part. The method of claim 1, Part of the air introduced into the third dust collecting unit is a dust collecting body structure of the vacuum cleaner, characterized in that introduced into the small cyclone through the vent hole. The method of claim 1, Dust collecting body structure of the vacuum cleaner, characterized in that the air discharge hole is formed so that the air introduced into the third dust collecting part is discharged to the first dust collecting part. The method of claim 4, wherein The ventilation hole is a dust collecting body structure of the vacuum cleaner, characterized in that formed around the air discharge hole. The method of claim 1, Dust collecting body structure of the vacuum cleaner, characterized in that the vent is provided with a net for filtering fine dust. The method of claim 6, The net is surrounded on the outer circumferential surface or the inner circumferential surface of the small cyclone portion, or the dust collecting body structure of the vacuum cleaner, characterized in that mounted on the inner circumferential surface of the vent hole.

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