KR100871485B1 - Method For Operating Dust Compressing Type of Dust Collector - Google Patents

Abstract

The present invention is to provide a method of operating a dust compaction dust collector to minimize the volume of dust stored in the dust container. To this end, the present invention, the first pressing plate rotatably installed in the dust container is rotated in one direction by the drive motor, compressing the dust on one side of the second pressing plate provided inside the dust container (a1) It provides a method of operating a dust compression dust collecting device comprising.

Therefore, according to the present invention, the dust collection amount which can be collected inside the dust container can be maximized, thereby improving the convenience of use.

Vacuum cleaner, dust box, pressure plate, drive gear, driven gear

Description

Method for Operating Dust Compressing Type of Dust Collector}

1 is a perspective view showing the appearance of a conventional vacuum cleaner;

2 is a longitudinal sectional view schematically showing a dust collector provided in a conventional vacuum cleaner;

3 is a perspective view showing a vacuum cleaner separately from a cleaner body and a dust collecting unit to which a driving method of a dust compression type dust collecting device according to the present invention is applied;

4 is a longitudinal sectional perspective view of a dust collecting unit applied to the vacuum cleaner of FIG. 3;

5 is an enlarged cutaway perspective view of a portion “A” of FIG. 4;

FIG. 6 is an exploded perspective view illustrating a coupling state of a driving unit provided to compress dust of the dust collecting unit illustrated in FIG. 3;

FIG. 7 is a perspective view of the cyclone and the dust container of the dust collecting unit illustrated in FIG. 3 separately;

FIG. 8 is a perspective view of the cyclone illustrated in FIG. 7 viewed from the lower side;

9 is a flow chart showing a method of operating a dust compression type dust collecting apparatus according to the present invention;

FIG. 10 is a flow chart showing an embodiment of step S100 shown in FIG. 9;

11A to 11E are plan views illustrating a process of compressing dust in the dust container of the dust collecting unit applied to the vacuum cleaner according to the present invention.

<Description of Symbols for Major Parts of Drawings>

100: cleaner body 200: dust collector

210: dust separator 211: cyclone

220: dust container 221: dust chamber

310: first pressing plate 320: second pressing plate

400: drive unit 410: driven gear

420: drive gear 430: drive motor

The present invention relates to a vacuum cleaner and a dust collecting apparatus, and more particularly, to a dust collecting apparatus having an increased dust collecting capacity and a vacuum cleaner having the same.

Hereinafter, a conventional vacuum cleaner will be described with reference to FIGS. 1 and 2.

1 and 2, a conventional vacuum cleaner includes a suction nozzle 11 for sucking external air containing dust, a cleaner body 20 in communication with the suction nozzle 11, and the suction nozzle An extension pipe 13 for guiding the air sucked by the (11) to the cleaner body 20 side, and a connecting pipe 15 for connecting the air passed through the extension pipe 13 to the cleaner body 20, It is composed.

Here, a nozzle suction port (not shown) of a predetermined size is formed at the bottom of the suction nozzle 11 to allow the air containing the dust accumulated on the floor to be sucked.

In addition, a cleaner handle 21 for transporting a cleaner is provided at the front of the cleaner body 20, and both sides of the cleaner body 20 may move the bottom surface of the cleaner body 20 smoothly. The moving wheels 23 are rotatably mounted respectively. In addition, the bottom front of the cleaner body 20 is provided with a caster (not shown) of the rotating material to change the direction of the cleaner body 20.

On the other hand, the inside of the cleaner body 20, a driving unit (not shown) for generating an air suction force to suck the outside air containing dust into the suction nozzle (11).

In addition, a dust collecting device 30 for separating and storing dust is detachably mounted to the rear of the cleaner body 20. The dust collecting device 30 performs a function of separating and storing dust contained in the air sucked by the suction nozzle 11.

In addition, a cord reel (not shown) is installed in the cleaner body 20, and the cord reel has a function of winding and storing an electric wire for supplying power to a driving unit provided in the cleaner body 20. And a cord reel button 25 for manipulating the operation of the cord reel is provided on the upper side of the cleaner body.

Next, with reference to Figure 2, the detailed configuration and operation principle of the dust collector provided in the conventional vacuum cleaner will be described.

The dust collector shown in FIG. 2 is a cyclone dust collector that separates and stores dust by using a cyclone principle, that is, a centrifugal force difference between air and dust, and has recently been applied to a vacuum cleaner to improve dust collection performance.

Here, the dust collecting device 30 is provided in the main cyclone unit 40 to collect relatively large dust by sucking the polluted air from the outside, and the auxiliary cyclone unit downstream of the main cyclone unit 40 to collect relatively small dust. It comprises a cyclone unit 50.

The main cyclone unit 40 is formed on the upper portion of the cylindrical container to separate the dust by centrifugal force.

Here, a first air suction part 41 is formed on the outer circumferential surface of the cylindrical container to introduce contaminated air containing foreign matter in the tangential direction, and an exhaust member having a hollow formed on an axis of the main cyclone unit 40. 43) is formed. In addition, a first air discharge part 45 through which the air passing through the exhaust member 43 is discharged is formed at the upper center portion of the cylindrical container.

Next, the auxiliary cyclone unit 50 serves to separate the dust contained in the air discharged from the main cyclone unit 40 again by the cyclone principle, and the upper circumference of the main cyclone unit 40 A plurality of small cyclones 51 are arranged along the circumferential direction.

Although not shown, air discharged from the main cyclone unit 40 through the first air discharge unit 45 is introduced into the secondary cyclone unit 50, and the dust is separated again from the small cyclones 51. After the process, it is discharged from the auxiliary cyclone unit 50 through the second air outlet (55).

Meanwhile, the dust separated by the main cyclone unit 40 and the auxiliary cyclone unit 50 is stored in the dust bins 47 and 57. The dust bins 47 and 57 are provided at a lower portion of the main cyclone unit 40 to store dust separated by the main cyclone unit 40, and the auxiliary cyclone unit 50. It is provided in the lower portion of the auxiliary chamber (57) for storing the dust separated by the secondary cyclone unit (50).

The main chamber 47 and the auxiliary chamber 57 are integrally formed under the main cyclone unit 40 and the auxiliary cyclone unit 50, and the auxiliary chamber 57 is the main chamber 47. It is configured to surround.

Therefore, the dust separated by the cyclone units is accumulated inside the dust container while falling.

On the other hand, in recent years, in order to improve the convenience of the cleaner use, efforts have been made to maximize the dust collecting capacity of the dust collected in the dust container.

However, in the related art, since the dust stored in the dust container is accumulated in the inflated state, that is, the density is very low, the user must empty the dust container frequently, and the dust is easily scattered, so that the dust separation performance is reduced. In addition, when the dust collector is stopped, it sinks in the bottom of the dust container and is stored in a low density state.

In other words, since the dust inside the dust container occupies a volume too large for its weight, there was an inconvenience of frequently emptying the dust container to maintain dust collecting performance.

Therefore, in recent years, the dust compression method for efficiently compressing dust together with the development of a dust collecting apparatus having a structure for compressing dust inside the dust container in order to maximize the dust collecting capacity of the dust collected in the dust container and improve the dust collecting performance. Development is required.

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a method of operating a dust compression type dust collecting apparatus to maximize dust collection capacity.

Another object of the present invention is to provide a convenient dust collecting apparatus for emptying the dust.

Still another object of the present invention is to provide a dust collecting device in which dust compression is automatically performed.

In order to achieve the above object, the present invention, the first pressure plate rotatably installed in the dust container is rotated in one direction by the drive motor, compressing the dust of one side of the second pressure plate provided inside the dust container It provides a method of operating a dust compaction dust collecting device comprising the step (a1).

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In the description of this embodiment, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted.

First, referring to Figure 3, the basic configuration of an embodiment of a vacuum cleaner according to the present invention will be described.

Here, a perspective view of a vacuum cleaner to which the driving method of the dust compression type dust collecting device according to the present invention is applied is separated from a cleaner body and a dust collecting unit.

The vacuum cleaner to which the operating method of the dust compression type dust collector according to the present embodiment is applied includes a suction nozzle 11 (see FIG. 1), a cleaner body 100, and a dust collector 200 for separating and storing dust. It is configured by.

The suction nozzle 11 (refer to FIG. 1) is for inhaling outside air containing dust, and thus, a detailed description thereof will be omitted.

The lower surface of the front surface of the cleaner body 100 is provided with a main body suction port 110 in communication with the suction nozzle, one side of the cleaner body 100 through the dust collector 200, the air is separated dust The main body discharge part 120 is discharged.

In addition, the inside of the cleaner body 100 is provided with an air suction device (not shown) for generating an air suction force. Here, the air intake device comprises a fan-motor assembly provided on the air flow path in communication with the dust collector 200, the fan-motor assembly is a suction port formed on the bottom of the suction nozzle of the outside Generate air suction force so that air is sucked in.

More specifically, the fan-motor assembly includes a motor and a blowing fan for forcing the flow of air while rotating by the motor.

In addition, the cleaner body 100 may be provided with wheels (not shown) for moving the cleaner body 100. Although not shown, the wheels may be provided in a roller-like form, one at each of the bottom front part and the rear part of the cleaner body 100.

The dust collector of the vacuum cleaner according to the present invention comprises a dust collecting unit (210, 220) for separating and storing the dust contained in the flowing air.

In addition, the dust collecting units 210 and 220 include a dust separator 210 for separating dust contained in the flowing air, and a dust container 220 for storing dust separated by the dust separator 210. It is configured by.

Here, the dust separation unit 210, the cyclone (211) for separating the dust contained in the air flowing from the suction nozzle to the main body outlet 120, the dust by the difference in centrifugal force between the air and dust It is configured to include. Therefore, the dust separated by the cyclone 211 is stored in the dust container 220.

The dust collecting unit is preferably detachably mounted to the cleaner body (100).

On the other hand, the dust collector 200 is preferably configured to maximize the dust collecting capacity of the dust stored therein. To this end, it is preferable that a configuration for reducing the volume of dust stored in the dust container 220 is added to the dust collecting unit.

4 to 7, the dust collecting apparatus according to the present invention in which dust collecting capacity is maximized will be described.

4 is a longitudinal cross-sectional perspective view of a dust collecting unit applied to the vacuum cleaner of FIG. 3, FIG. 5 is a cutaway perspective view showing an enlarged portion “A” of FIG. 4, and FIG. 6 shows dust of the dust collecting unit shown in FIG. 3. 7 is an exploded perspective view illustrating a coupling state of a driving unit provided to compress, and FIG. 7 is a perspective view showing a cyclone and a dust container separated from the dust collecting unit shown in FIG. 3, and FIG. 8 is a lower portion of the cyclone shown in FIG. This is a perspective view.

The dust collecting unit is detachably housed in the dust collecting unit mounting unit 130 provided in the cleaner body 100. Here, the dust collecting unit mounting unit 130 is provided in the front portion of the cleaner body may be provided in a different position.

In addition, the dust collecting unit is provided with a pair of pressure plates 310 and 320 to reduce the volume of dust stored in the dust container 220 to increase dust collection capacity.

Here, the pair of pressure plates 310 and 320 compresses the dust by interaction with each other to reduce the volume of the dust, and thus the mass per unit volume of the dust stored in the dust container 220, that is, As the density increases, the maximum dust collecting capacity of the dust container 220 is increased.

In the present embodiment, at least one of the pair of pressure plates 310 and 320 is provided to be movable inside the dust container 220, and between the pair of pressure plates 310 and 320. Dust is compressed

In other words, when all or one of the pair of pressure plates 310 and 320 moves, and the gap between the pair of pressure plates 310 and 320 narrows, the pair of pressure plates 310 and 320 may be reduced. As the dust in between is collected, the dust is compressed to a high density.

The pair of pressure plates 310 and 320 are provided inside the dust container 220, and for convenience of description, one of the pair of pressure plates 310 and 320 is referred to as a first pressure plate 310. The other one is referred to as a second pressing plate 320.

In the dust collector according to the present invention, it is preferable that at least one of the first pressing plate 310 and the second pressing plate 320 is rotatably provided in the dust container 220.

When both the first pressing plate 310 and the second pressing plate 320 are rotatably provided in the dust container 220, both the first pressing plate 310 and the second pressing plate 320 face each other. While rotating, the distance between one side of the first pressing plate 310 and one side of the second pressing plate 320 opposite to one side of the first pressing plate 310 is narrowed, and accordingly the Dust located between the first pressing plate 310 and the second pressing plate 320 may be compressed.

However, in the present embodiment, the first pressing plate 310 is provided to be rotatable inside the dust container 220. In addition, a dust chamber 221 is formed inside the dust container 220 to form a space for storing dust.

More specifically, the inner circumferential surface of the dust chamber 221 so that the free end 311 of the first pressure plate 310 may surround the trajectory that is drawn while rotating when the first pressure plate 310 is rotated, It is rotatably connected to the inside of the dust chamber 221.

In other words, the inner circumferential surface of the dust chamber 221 surrounds the outer circumference of the virtual rotary body formed while the first pressing plate 310 rotates.

In addition, although the second pressing plate 320 may be rotatably provided in the dust chamber 221, in the present embodiment, the second pressing plate 320 is provided at a fixed position inside the dust chamber 221. Accordingly, the first pressing plate 310 is a rotating plate, the second pressing plate 320 is a fixed plate.

Here, the second pressing plate 320 is preferably provided between the inner circumferential surface of the dust chamber 221 and the axis of the rotating shaft 312 forming the rotation center of the first pressing plate 310.

More specifically, the second pressing plate 320 forms a wall provided on a surface connecting the axis of the rotary shaft 312 and the inner circumferential surface of the dust chamber 221.

In other words, the second pressing plate 320 completely or partially shields a passage between the inner circumferential surface of the dust chamber 221 and the axis of the rotating shaft 312 so that the dust is prevented by the first pressing plate 310. When pressed, the dust is compressed together with the first pressing plate 310.

To this end, one end 321 of the second pressing plate 320 is integrally formed on the inner circumferential surface of the dust chamber 221, the other end is fixed shaft (coaxially provided with the rotating shaft 312 of the first pressing plate ( 322 is integrally formed.

Of course, only one end of the second pressing plate 320 may be integrally formed on the inner circumferential surface of the dust chamber 221 or only the other end may be integrally formed on the fixed shaft 322. In other words, the second pressing plate 320 is fixed to at least one side of the inner circumferential surface of the dust chamber 221 and the fixed shaft 322.

However, even if one end of the second pressure plate 320 is not integrally connected to the inner circumferential surface of the dust chamber 221, one end of the second pressure plate 320 is adjacent to the inner circumferential surface of the dust chamber 221. desirable. Further, even if the other end of the second pressure plate 320 is not integrally connected to the fixed shaft 322, the other end of the second pressure plate 320 may be adjacent to the fixed shaft 322.

The reason is to minimize the leakage of dust pushed by the first pressing plate 310 through the gap formed on the side of the second pressing plate 320.

In addition, the second pressing plate 320 may be integrally connected to one end of the dust chamber 221 or adjacent to one end of the dust chamber 221.

The first pressing plate 310 and the second pressing plate 320 configured as described above is preferably composed of a square plate. In addition, the rotation shaft 312 of the first pressing plate 310 is preferably provided coaxially with the axis forming the center of the dust chamber 221. In addition, the dust chamber 221 preferably has a cylindrical inner space.

Here, the free end, that is, the outer end of the first pressing plate 310 is preferably rotatable in a state as close as possible to the inner circumferential surface of the dust chamber 221.

On the other hand, the fixed shaft 322 preferably protrudes inward from one end of the dust chamber 221, the inside of the fixed shaft 322 is penetrated in the axial direction for the assembly of the rotating shaft 312 A hollow is formed, and one end of the dust chamber 221 is formed with a through hole (not shown) in communication with the hollow inside the fixed shaft 322.

4 to 6, the vacuum cleaner according to the present invention further includes a driving unit 400 connected to the rotation shaft 312 of the first pressing plate to rotate the first pressing plate 310. It is desirable to be.

The driving unit 400 includes power transmission units 410 and 420 for transmitting a force for rotating the first pressure plate 310 to the rotation shaft of the first pressure plate.

Here, the power transmission unit 410, 420, the driven gear 410 is coupled to the rotary shaft 312 of the first pressing plate, and the drive gear 420 for transmitting power to the driven gear 410. It is configured by.

In addition, the driving gear 420 is coupled to the rotation shaft of the dust compression driving motor 430 is rotated by the drive motor 430.

Accordingly, the first pressing plate 310 is automatically rotated to compress the dust stored in the dust container 220.

In this embodiment, one end of the dust container 220 forms the bottom of the dust container 220 and at the same time forms one end of the dust chamber 221, and the bottom 222 of the dust container is the dust collecting unit mounting portion ( 130) is supported by the bottom.

In addition, the driving motor 430 is provided at the lower side of the dust collecting unit mounting unit 130, and the driving gear 420 is coupled to the shaft by the driving motor 430, and the bottom of the dust collecting unit mounting unit 130. Is provided.

In more detail, the driving motor 430 is mounted to the bottom side of the dust collecting unit mounting unit 130. In addition, the drive gear 420 is connected to the rotation shaft of the drive motor 430 is installed on the bottom surface of the dust collecting unit mounting unit 130, a portion of the outer peripheral surface of the drive gear 420 is the dust collecting unit mounting unit 130 Exposed to the outside from the bottom of.

To this end, it is preferable that a motor accommodating part (not shown) in which the driving motor 430 is installed is formed below the bottom of the dust collecting unit mounting part 130, and the center of the bottom of the dust collecting unit mounting part 130 is formed. An opening for exposing a portion of the outer circumferential surface of the drive gear 420 to the outside is formed.

On the other hand, the rotating shaft 312 of the first pressing plate is rotatably installed through the bottom of the dust chamber 221 and the hollow of the fixed shaft 322, the lower end of the rotating shaft 312 is the driven gear ( 410 is combined.

Here, the rotating shaft 312 is the upper shaft 312a to which the first pressing plate 310 is coupled so that the rotating shaft 312 to which the first pressing plate 310 is coupled may be assembled to the dust container 220. And the lower shaft 312b to which the driven gear 410 is coupled.

A stepped portion supported by the upper end of the fixed shaft 322 is formed on the upper shaft 312a, and the lower end of the upper shaft 312a is coupled to the upper end of the lower shaft 312b.

In more detail, the upper shaft 312a is inserted into the hollow in a predetermined depth from the upper side of the fixed shaft 322. The lower shaft 312b is inserted into the hollow of the fixed shaft 322 through the through hole (not shown) formed at one end of the dust chamber 221, that is, the bottom of the dust container 220.

Here, the upper end of the lower shaft 312b is coupled to the lower end of the upper shaft 312a, and the upper shaft 312a and the lower shaft 312b rotate integrally.

A coupling protrusion is formed on one side of the upper shaft 312a and the lower shaft 312b so that the upper shaft 312a and the lower shaft 312b are integrally rotated, and the coupling groove is formed on the other side. It is preferable.

For example, a coupling protrusion of "-" or "+" shape is formed on the lower surface of the upper shaft 312a, and the "-" or "+" character on the upper surface of the lower shaft 312b. The coupling groove of the type | mold is mentioned.

In addition, the driven gear 410 is integrally coupled to the lower end of the lower shaft 312b and installed below the bottom of the dust container 220.

Accordingly, a part of the outer circumferential surface of the driving gear exposed to the outside from the bottom of the dust collecting unit mounting unit 130 is, as the dust container 220 is mounted on the dust collecting unit mounting unit of the cleaner body, under the bottom of the dust container 220. It is engaged with the driven gear 410 provided on the side.

On the other hand, the drive motor 430 is preferably made of a motor capable of forward rotation and reverse rotation. In other words, the drive motor 430 is a motor capable of bidirectional rotation.

In addition, the drive motor 430, it is preferable to continuously rotate the first pressure plate 310 forward / reverse at the same angular speed so that the compression of the dust can be made easily.

Here, the drive motor 430 may be made of a synchronous motor. Since the synchronous motor is generally known in the motor art, a detailed description thereof will be omitted.

Accordingly, the first pressing plate 310 can be rotated forward and reverse, and as the first pressing plate 310 rotates forward and reverse, the first pressing plate 310 is compressed on both sides of the second pressing plate 320. Dust will accumulate.

The first pressure plate 310 continuously presses the dust for a predetermined time even after the first pressure plate 310 rotates to reach a peak that can no longer rotate while compressing the dust. Even after the 310 reaches the peak, it is preferable that the power of the driving motor transmitted to the rotation shaft 312 lasts for a predetermined time.

In addition, any one of the first pressing plate 310 and the second pressing plate 320 may be spaced apart from the compressed dust in order to facilitate the emptying of the dust stored in the dust container 220.

As in the present embodiment, when the first pressing plate 310 is a rotating plate, and the second pressing plate 320 is a fixed plate, the first pressing plate 310 is spaced from the compressed dust to empty the dust.

Accordingly, since the dust compressed in the dust chamber 221 contacts only the inner circumferential surface of the dust chamber 221 and the second pressing plate 320, the dust container 220 may be easily emptied.

In addition, when the dust is collected in a predetermined amount or more inside the dust chamber 221, in order to prevent the deterioration of the dust collection performance and the overload of the motor, it is preferable to display the emptying time of the dust container 220 to the user.

To this end, an alarm indicator (not shown) is installed on the cleaner main body 100 or the dust collecting unit, and dust of a predetermined amount or more is collected inside the dust chamber 221 to rotate the first pressure plate 310. When the range is less than or equal to a predetermined angle, the empty timing of the dust container 220 is displayed to the user.

7 and 8, the dust separation unit 210, that is, the cyclone 211 is preferably provided on the upper part of the dust container 220.

In more detail, the cyclone 211 is preferably located above the dust chamber 221. In addition, an upper circumferential surface of the cyclone 211 is provided with a suction port 211a in a substantially tangential direction so that air containing dust is sucked in, and the ceiling central portion of the cyclone 211 is primarily dust inside the cyclone 211. The outlet 211b through which the separated air is discharged is formed.

In addition, a hollow exhaust member 211c is coupled to the outlet 211b, and a plurality of through-holes through which dust is discharged from the inside of the cyclone 211 are discharged to the outer circumferential surface of the exhaust member 211c. Is formed.

Here, the ceiling of the cyclone 211 is formed by a cover 211d detachably coupled to the upper edge of the cyclone.

In addition, the cyclone 211 and the dust container 220 is partitioned by the partition plate 230. In the present embodiment, the partition plate 230 forms a ceiling of the dust chamber 221.

Here, the upper ends of the first pressure plate 310 and the second pressure plate 320 may be adjacent to the bottom surface of the partition plate 230.

In addition, the partition plate 230 forms a dust inlet 231 (see FIG. 8) provided at an edge thereof so that the dust separated from the cyclone 211 flows into the dust chamber 221.

Here, the dust inlet 231 is formed by recessing a portion of the edge of the partition plate 230 toward the center of the partition plate 230.

In addition, the dust inlet 231 is preferably located on the opposite side of the second pressure plate (320).

The reason is that by maximizing the amount of dust compressed on both sides of the second pressing plate 320, the dust collecting capacity of the dust is maximized while the dust is scattered in the process of storing the dust inside the dust chamber 221. This is to minimize.

In the present embodiment, the dust container 220 is separated from the cleaner body 100 separately from the cyclone 211. To this end, the dust container 220, is detachably provided at the lower portion of the cyclone. In addition, the partition plate 230 is integrally formed with the cyclone 211 to form a bottom of the cyclone 211.

Here, the remaining portion except for a portion of the edge of the partition plate 230 forming the dust inlet 231 is integrally connected to the bottom edge of the cyclone 211, the pair of pressure plates 310, The dust is prevented from rising to the upper portion of the partition plate 230 in the process of compressing the dust by 320, and the dust is prevented from being scattered by the spiral flow inside the cyclone 211.

Accordingly, the user may perform the dust emptying by separating only the dust container 220. When the inside of the cyclone 211 is required to be cleaned, the user can easily clean the inside of the cyclone 211 by separating the cyclone 211 from the cleaner body 100 and separating the cover 211d. Can be.

In order to detach the cyclone 211 and the dust container 220 as described above, an upper handle 212 and a lower handle 223 are provided on the outer circumferential surface of the cyclone 211 and the outer circumferential surface of the dust container 220, respectively. .

In addition, in order to couple the dust container 220 and the cyclone 211 in a state in which the dust container is mounted on the lower side of the cyclone 211, the dust collecting unit is provided with a hook device.

In more detail, a hook hook 241 is installed at a lower end of the outer circumferential surface of the cyclone 211, and a hook portion 242 is provided at the upper circumferential surface of the dust container 220 to selectively hook the hook hook 241. By being combined, the dust container 220 is fixed to the lower end of the cyclone 211.

Meanwhile, when the cyclone 211 described above is called a main cyclone and the dust chamber 221 is called a main chamber, the dust collector according to the present invention includes at least one auxiliary cyclone (not shown) provided in the cleaner body 100. Si) and the auxiliary dust chamber 224 provided in the dust collecting unit may be further configured.

Here, the auxiliary cyclone secondaryly separates the dust contained in the air discharged from the main cyclone 211, and the secondary dust chamber 224 stores the dust separated from the secondary cyclone. do.

In addition, the auxiliary dust chamber 224 is provided on the outer circumferential surface of the dust collecting unit with the upper end open.

In the present embodiment, the auxiliary dust chamber 224 is provided on the outer circumferential surface of the dust container 220, the auxiliary dust inlet 213 communicating with the auxiliary dust chamber 224 on the outer circumferential surface of the main cyclone 211. ) Is provided.

Here, the auxiliary dust inlet 213a is formed on the outer wall of the auxiliary dust inlet 213 and is selectively connected to the dust outlet 140 of the auxiliary cyclone, and the bottom of the auxiliary dust inlet 213 is open. And is connected to the top of the auxiliary dust chamber 224.

Accordingly, when the main cyclone 211 is mounted on the cleaner body, the auxiliary dust inlet 213a is connected to the dust outlet 140 of the auxiliary cyclone, and the dust container 220 is connected to the cleaner body 100. When mounted at the lower side of the main cyclone 211, the auxiliary dust inlet 213 and the auxiliary dust chamber 221 is in communication with each other.

Therefore, the dust separated from the auxiliary cyclone is introduced through the auxiliary dust inlet 213a and stored in the auxiliary dust chamber 221.

An operation method of the dust compaction dust collecting device configured as described above will be described in detail with reference to FIGS. 9 and 10.

Operation method of the dust-collecting dust collector according to the present invention (hereinafter abbreviated as dust compression method), by compressing the dust stored in the dust container by the interaction of a pair of pressure plates (a) step (S100) It is made to include.

The dust compression method may further include (b) step (S200) of detecting a rotation range θ of the first press plate 310 according to the present invention. good.

In addition, the dust compression method, if the rotation range (θ) of the first pressing plate 310 is limited to less than a predetermined angle (θ _p ) by the dust stored in the dust container 220 and compressed to the outside Notifying may further include step (c) (S300).

In more detail, step (c) (S300), comparing the rotation range (θ) of the first pressing plate 310 with a predetermined angle (θ _p ) (S310) and the first If the rotation range (θ) of the pressure plate 310 and the predetermined predetermined angle (θ _p ) or less, it includes a step (S320) to inform the outside.

Here, step (c) S300 may be performed by an alarm or a warning lamp.

On the other hand, step (a) (S100), by rotating the first pressing plate 310 rotatably installed in the dust container in one direction to compress the dust on one side of the second pressing plate 320 (a1) Step S110 is included.

In addition, the step (a) (S100), further comprising the step (a2) (S120) of compressing dust on the opposite side of the second pressure plate 320 by rotating the first pressure plate 310 in the opposite direction. It is desirable to.

In addition, the step (a); It is preferable that the first pressing plate 310 further comprises (a3) steps (S130, S140) of continuously pressing dust for a predetermined time in a state where it reaches a peak that can no longer rotate.

Here, the first pressing plate 310 is repeated to rotate in a direction opposite to one direction at a predetermined angular speed.

A process of compressing dust by the dust compression method as described above will be described with reference to FIGS. 10A to 10E.

First, when power is supplied to a vacuum cleaner, an air suction force is generated by the air suction device, and external air containing dust is sucked into the suction nozzle by the air suction force.

The outside air sucked through the suction nozzle is introduced into the suction port 211a of the main cyclone through the main body suction port 110.

Air introduced through the inlet port 211a of the main cyclone is guided in a tangential direction to the inner wall of the main cyclone 211 to form a spiral flow, so that the dust contained in the air due to the difference in centrifugal force with the air Separated and descended.

As described above, the dust falling while spirally flowing along the inner wall of the main cyclone 211 passes through the dust inlet 231 of the partition plate 230 and is stored in the main chamber 221.

The air from which dust is first separated by the main cyclone 211 is discharged through the discharge port 211b through the exhaust member 211c and then flows into the auxiliary cyclone.

Accordingly, the dust separated by the cyclone principle inside the auxiliary cyclone is stored in the auxiliary dust chamber 224, and the air which has undergone the dust separation process again in the auxiliary cyclone is discharged from the auxiliary cyclone, and then the fan- It is discharged from the cleaner body 100 through the body discharge unit 120 via a motor assembly.

Meanwhile, the main chamber 221 stores most of the dust introduced into the vacuum cleaner, and the dust inside the main chamber 221 is formed on the first pressing plate 310 and the second pressing plate 320. By compressing by minimizing the volume, it is possible to store a large amount of dust inside the main chamber 221.

In more detail, as shown in FIG. 11A, the first pressing plate 310 rotates in one direction toward one side of the second pressing plate 320 to sweep and press the dust inside the main chamber 221. While reducing the volume of dust.

When the first pressing plate 310 reaches the peak, dust is continuously pressed to one side of the second pressing plate for a predetermined time (about 3 to 5 seconds).

Next, as shown in FIG. 11B, the first pressing plate 310 rotates in the opposite direction toward the opposite side of the second pressing plate 320 to collect and press the dust inside the main chamber 221 and press the dust. Reduce the volume of

When the first pressing plate 310 reaches the peak, dust is continuously pressed to the opposite side of the second pressing plate 320 for a predetermined time (about 3 to 5 seconds).

This process is repeated continuously during operation of the vacuum cleaner, as shown in Figs. 11A to 11D.

On the other hand, the rotation range of the first pressing plate 310 during the operation of the vacuum cleaner is input to the control unit of the cleaner body 100, and thus the amount of dust collected in the dust container 220 is roughly calculated.

As shown in FIG. 11E, when the rotation range of the first pressing plate 310 is narrowed below a predetermined angle, the user is notified to the outside.

As described above, the dust container 220 in which dust is stored in a compressed state therein is separated from the cleaner body 100 by the user at an appropriate time and is emptied.

In other words, when the user detaches the dust container 220 from the cleaner body 100 and flips the dust container 220, the compressed dust inside the dust container is discharged to the outside.

In addition to the embodiments described above, the fact that the present invention can be embodied in other specific forms without departing from the spirit and scope will be apparent to those skilled in the art.

Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above detailed description, but may vary within the scope of the appended claims and their equivalents.

The vacuum cleaner according to the present invention having the above configuration has the following effects.

First, according to the operation method of the dust compression dust collector according to the present invention, since the dust stored in the dust container is compressed to minimize its volume, the dust collecting capacity of the dust stored in the dust container is maximized, and the convenience of use. This is improved.

Second, according to the operation method of the dust compression type dust collecting apparatus according to the present invention, when a predetermined amount or more of dust is collected in the inside of the dust container, the emptying time of the dust box is displayed, it is easy to know when to empty the dust.

Third, according to the dust collector according to the present invention, since the first pressing plate is repeated in the forward direction and the reverse direction, the dust compression performance is improved.

Claims (8)

The first dust plate rotatably installed in the dust container is rotated in one direction by a drive motor, and the dust compaction dust collecting device includes a step (a1) of compressing dust on one side of the second pressure plate provided inside the dust container. How to operate. The method of claim 1, The drive motor is a method of operating a dust-collecting dust collector, characterized in that the motor capable of forward and reverse rotation. The method of claim 2, And (a2) the first pressing plate is rotated in the opposite direction by the driving motor to compress dust on the opposite side of the second pressing plate. The method of claim 3, wherein Operating method of the dust-compressing dust collector for continuously pressing the dust for a predetermined time in a state where the first pressure plate reaches a peak that can no longer rotate. The method of claim 3, wherein The first pressing plate is a method of operating a dust-collecting dust collecting device is repeated to rotate in a direction opposite to one direction at a constant angular speed.  The method of claim 3, wherein  And (b) detecting the rotation range of the first pressing plate. The method of claim 6, And (c) notifying outside when the rotation range of the first pressing plate is limited to a predetermined angle or less by the dust stored and compressed in the dust container. The method of claim 7, wherein Step (c) is; Operation method of dust-compact dust collector performed by alarm or warning lamp.

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