KR101286853B1 - Vacuum cleaner - Google Patents

Abstract

The present embodiment relates to a vacuum cleaner, and more particularly, to a vacuum cleaner in which a dust collecting capacity of a dust collecting device is maximized.

Vacuum cleaner according to the present embodiment includes a cleaner body; A dust collecting device detachable from the cleaner body and having a dust storage unit formed therein; A pressing member compressing the dust stored in the dust storage unit; And a driving device provided to the dust collecting device to drive the pressing member. According to this embodiment, since the dust stored in the dust collector is compressed by the pressing member to minimize its volume, there is an effect of maximizing the capacity of the dust stored in the dust collector.

Dust, compressed

Description

Vacuum cleaner

1 is a perspective view of a vacuum cleaner according to a first embodiment;

2 is a perspective view of a vacuum cleaner of which a dust collecting device is separated.

3 is a perspective view of a dust collecting device according to the first embodiment;

4 is a cross-sectional view taken along the line II ′ of FIG. 3.

5 is a perspective view of a dust collecting unit mounting portion according to the first embodiment.

6 is a vertical sectional view of the vacuum cleaner according to the first embodiment.

7 is a vertical sectional view of the vacuum cleaner according to the second embodiment.

8 is a cross-sectional view taken along line II-II 'of FIG.

9 is a vertical sectional view of the dust collecting apparatus according to the third embodiment.

10 is a perspective view of a state in which the dust collecting apparatus is separated from the vacuum cleaner according to the fourth embodiment.

11 is an exploded perspective view of the dust collecting apparatus according to the fourth embodiment.

12 is a cross-sectional view taken along line III-III 'of FIG. 10;

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

100: main body 200: dust collector

270: first pressing member 280: second pressing member

400, 500: drive unit

The present embodiment relates to a vacuum cleaner, and more particularly, to a vacuum cleaner in which a dust collecting capacity of a dust collecting device is maximized.

Generally, a vacuum cleaner sucks air containing dust by using vacuum pressure generated by a suction motor mounted inside the main body, and then filters dust inside the main body.

The vacuum cleaner includes a suction nozzle for sucking dust-containing air, a vacuum cleaner main body communicating with the suction nozzle, an extension pipe for guiding air sucked from the suction nozzle to the vacuum cleaner main body, And a connector for connecting to the cleaner main body.

Here, a nozzle suction port of a predetermined size is formed on the bottom of the suction nozzle to allow the air containing the dust accumulated on the floor to be sucked.

On the other hand, the inside of the cleaner body, there is provided a suction device for generating an air suction force to suck the outside air containing dust to the suction nozzle.

A dust collecting device for separating and storing dust is removably mounted on the cleaner main body. The dust collector performs a function of separating and storing dust contained in the air sucked from the suction nozzle.

In particular, the dust collecting apparatus includes a dust collecting body, a suction port through which air is sucked by the dust collecting body, a cyclone separating dust from the air sucked into the dust collecting body, And a discharge port through which dust is separated from the cyclone portion.

When the operation of the vacuum cleaner is stopped while the dust separating process is being performed in the dust collecting apparatus, the separated dust is stored in the dust storing unit in a low density state.

According to such a conventional dust collecting apparatus, the dust stored in the dust storing unit occupies an excessively large volume compared with the weight of the dust collecting apparatus. Therefore, it is inconvenient to frequently empty the dust of the dust collecting apparatus in order to maintain the dust collecting performance.

Therefore, in recent years, efforts have been made to improve the dust collecting performance while maximizing the dust capacity stored in the dust collecting apparatus, in order to improve the convenience of use of the vacuum cleaner.

The proposed embodiment is to solve the problems as described above, it is an object of the present invention to propose a vacuum cleaner to increase the dust collection capacity of the dust collector by compressing the dust stored in the dust collector.

In addition, another object of the embodiment is to propose a vacuum cleaner that is prevented from scattering dust in the process of discharging the dust stored in the dust collector.

Vacuum cleaner according to an embodiment for achieving the object as described above for separating the dust in the air; A dust collecting body in which a dust storage unit for storing dust separated from the dust separation unit is formed; A pressurizing member compressing dust stored in the dust storage unit and movable in the dust storage unit; A driving device detachably coupled to the dust collecting body, the driving device including a compression motor rotatable in both directions and a motor housing in which the compression motor is accommodated; A fastening part provided in the dust collecting body and coupled to the motor housing; A cleaner body into which air discharged from the dust separator is introduced; A mounting portion formed in the cleaner body and detachably mounted to the dust collecting body, wherein the mounting portion has a recess formed therein for mounting the driving device, and the motor housing is coupled to an outer wall of the dust collecting body, A terminal portion is formed in the motor housing, and a power supply terminal for contacting the terminal portion is formed in the seating groove of the mounting portion. When the terminal portion contacts the power supply terminal, power is supplied from the cleaner body to the compression motor. Characterized by being supplied

Hereinafter, this embodiment will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a vacuum cleaner according to a first embodiment, FIG. 2 is a perspective view of a vacuum cleaner in which a dust collecting device is separated, and FIG. 3 is a perspective view of a dust collecting device according to a first embodiment.

1 to 3, the vacuum cleaner 10 according to the present embodiment includes a cleaner main body 100 having a suction motor (not shown) that generates suction force therein, and the cleaner main body 100. And dust separating means for separating the dust contained in the sucked air.

Although not shown, a suction nozzle for sucking dust-containing air and a connection pipe for connecting the suction nozzle to the cleaner body 100 are further included.

In the present embodiment, the basic configuration of the suction nozzle and the connection pipe is the same as the conventional description thereof will be omitted.

In detail, a main body suction part 110 in which air containing dust sucked from the suction nozzle (not shown) is formed at the front lower end of the cleaner body 100, and dust is provided at one side of the cleaner body 100. A main body discharge part (not shown) in which the separated air is discharged to the outside is formed. In addition, the upper portion of the cleaner body 100 is formed with a body handle 140 to enable the user to grip.

On the other hand, the dust separation means, the dust collecting device 200 is provided with a first cyclone unit (described later) for separating the dust contained in the air introduced into the inside, and the first cyclone unit is primarily The dust is separated again from the air from which the dust is separated, and is composed of a second cyclone unit 300 provided in the cleaner body 100.

In detail, the dust collecting apparatus 200 is detachably mounted to the dust collecting apparatus mounting unit 170 formed at the front of the cleaner body 100. As such, the handle 140 of the cleaner body 100 is provided with a detachable lever 142 in order to allow the dust collector 200 to be detachably attached to the cleaner body 100, and the dust collector 200 is provided. There is a locking end 256 that is engaged with the detachable lever 142 is formed.

In addition, the dust collecting apparatus 200 includes a dust collecting body 210 in which a first cyclone unit generating a cyclone flow and a dust storage unit storing dust separated from the first cyclone unit are formed.

Here, the dust collector 200 is detachably mounted to the cleaner body 100 as described above, and as the dust collector 200 is mounted to the cleaner body 100, the dust collector 200 is The cleaner body 100 and the second cyclone unit 300 communicate with each other.

In detail, the cleaner main body 100 has an air outlet 130 through which the air sucked into the cleaner main body 100 is discharged to the dust collecting device 200, and the dust collecting device 200 has the air discharge port. A first air inlet 218 is formed to allow air to enter from 130.

In addition, a first air outlet 252 through which dust separated from the first cyclone part is discharged is formed in the dust collecting device 200, and the first air outlet 252 is formed in the cleaner body 100. A connection flow passage 114 through which air discharged through the air is introduced is formed.

In addition, air introduced into the connection channel 114 flows into the second cyclone unit 300. On the other hand, the second cyclone portion 300 is composed of a plurality of small cyclones of the conical shape is coupled.

In addition, the second cyclone unit 300 is disposed in a state lying down on the rear upper side of the cleaner body 100. That is, the second cyclone unit 300 is disposed in a state inclined at a predetermined angle with respect to the cleaner body 100.

Here, the dust separated from the second cyclone unit 300 is stored in the dust collector 200. To this end, the dust collecting body 210, the dust inlet 254 for the dust separated from the second cyclone portion 300 is introduced, and the dust separated from the second cyclone portion 300 is stored The reservoir is further formed.

That is, the dust storage unit formed in the dust collecting body 210 may include a first dust storage unit in which dust separated by the first cyclone unit is stored, and dust separated by the second cyclone unit 300. And a second dust storage portion to be stored.

On the other hand, the dust collecting device 200 is preferably configured to maximize the dust collecting capacity of the dust stored therein. To this end, the dust collecting apparatus 200 is preferably added to the configuration for reducing the volume of dust stored therein.

4 is a cross-sectional view taken along line II ′ of FIG. 3, and FIG. 5 is a perspective view of a dust collecting unit mounting part according to the first embodiment.

4 and 5, the dust collecting apparatus 200 according to the present embodiment includes a dust collecting body 210 forming an external shape, and dust is separated from the sucked air, which is selectively accommodated in the dust collecting body 210. The first cyclone unit 230 and a cover member 250 for selectively opening and closing the upper side of the dust collecting body 210 are included.

In detail, the dust collecting body 210 is formed in a substantially cylindrical shape, and a dust storage unit in which the separated dust is stored is formed therein.

The dust storage unit includes a first dust storage unit 214 in which dust separated from the first cyclone unit 230 is stored, and a second dust in which dust separated from the second cyclone unit 300 is stored. Dust storage unit 216 is included.

Here, the dust collecting body 210 is connected to the first wall 211 forming the first dust storage unit 214 and the second dust storage unit 216 in relation to the first wall 211. A second wall 212 that forms is included. That is, the second wall 212 is formed to surround the outer predetermined portion of the first wall 211. Therefore, the second dust storage unit 216 is formed outside the first dust storage unit 214.

On the other hand, the dust collecting body 210 has an upper end that is open so that a user can turn over the dust collecting body 210 to discharge dust, the cover member 250 is removable on the upper portion of the dust collecting body 210. To be combined.

In addition, when the dust stored in the dust collecting body 210 is discharged, the first cyclone portion 230 may be separated from the cover member 250 so as to be separated together with the cover member 250. Combined.

On the other hand, the first cyclone unit 230 is provided with a dust guide flow path 232 for guiding the dust separated from the air to be easily discharged to the first dust storage unit 214. Here, the dust guide flow path 232 is guided to fall downward after the separated dust flows in the tangential direction. Thus, the inlet 233 of the dust guide flow path 232 is formed on the side of the first cyclone portion 230, the outlet 234 is formed on the bottom surface of the first cyclone portion 230. .

On the other hand, the cover member 250 is detachably coupled to the upper side of the dust collecting body 210 as described above. That is, the cover member 250 opens and closes the first dust storage unit 214 and the second dust storage unit 216 at the same time.

In addition, a discharge hole 251 through which dust separated from the first cyclone part 230 is discharged is formed through the bottom surface of the cover member 250. The upper end of the filter member 260 having a plurality of through holes 262 of a predetermined size is coupled to the discharge hole 251. Therefore, the air that has undergone the dust separation process in the first cyclone unit 230 is discharged through the filter member 260 to the discharge hole 251.

In addition, a flow path 253 is formed inside the cover member 250 to guide air of the first cyclone part 230 discharged from the discharge hole 251 to the first air outlet 252. . That is, the flow path 253 serves as a passage connecting the discharge hole 251 and the first air outlet 252.

On the other hand, the dust collecting body 210 is provided with a pair of pressing members (270, 280) to reduce the volume of dust stored in the first dust storage unit 214, so that the dust collecting capacity of the dust increases.

Here, the pair of pressing members 270 and 280 compress the dust by interaction with each other to reduce the volume of the dust, and thus the density of the dust stored in the first dust storage unit 214. By increasing, the maximum dust collecting capacity of the dust collecting body 210 is increased.

Hereinafter, for convenience of description, any one of the pair of pressing members 270 and 280 is called a first pressing member 270, and the other is called a second pressing member 280.

In the present exemplary embodiment, at least one of the pair of pressing members 270 and 280 is provided to be movable in the dust collecting body 210, so that dust is separated between the pair of pressing members 270 and 280. Performs a compression action.

That is, when the first pressing member 270 and the second pressing member 280 are rotatably provided in the dust collecting body 210, the first pressing member 270 and the second pressing member 280 are rotatable. ) Rotates toward each other, the interval between one side of the first pressing member 270 and one side of the second pressing member 280 opposite to one side of the first pressing member 270 As a result, the dust positioned between the first pressing member 270 and the second pressing member 280 is compressed.

However, in the present embodiment, the first pressing member 270 is rotatably provided inside the dust collecting body 210, and the second pressing member 280 is fixed inside the dust collecting body 210. . Accordingly, the first pressing member 270 becomes a rotating member, and the second pressing member 280 becomes a fixing member.

In detail, the second pressing member 280 is preferably provided between the inner circumferential surface of the dust collecting body 210 and the axis of the rotating shaft 272 forming the rotation center of the first pressing member 270.

That is, the second pressing member 280 is provided on a surface connecting the axis of the rotation shaft 272 and the inner circumferential surface of the first dust storage unit 214. At this time, the second pressing member 280 completely or partially shields the space between the inner circumferential surface of the first dust storage unit 214 and the axis of the rotation shaft 272, and thus the first pressing member 270. When dust is pushed by), the dust is compressed together with the first pressing member 270.

To this end, one end of the second pressing member 280 is integrally formed on the inner circumferential surface of the dust collecting body 210, and the other end is fixed to the coaxial with the rotation shaft 272 of the first pressing member 270 It is preferably formed integrally with the shaft 282.

Of course, only one end of the second pressing member 280 may be integrally formed on the inner circumferential surface of the dust collecting body 210, or only the other end may be integrally formed on the fixed shaft 282. In other words, the second pressing member 280 is fixed to at least one side of the inner circumferential surface of the dust collecting body 210 and the fixing shaft 282.

However, even if one end of the second pressing member 280 is not integrally formed on the inner circumferential surface of the dust collecting body 210, one end of the second pressing member 270 is adjacent to the inner circumferential surface of the dust collecting body 210. It is preferable.

In addition, even if the other end of the second pressing member 280 is not integrally formed on the fixed shaft 282, the other end of the second pressing member 280 may be adjacent to the fixed shaft 282.

The reason is to minimize the leakage of dust pushed by the first pressing member 270 through the gap formed on the side of the second pressing member 280.

It is preferable that the 1st press member 270 and the 2nd press member 280 comprised as mentioned above are comprised by the plate of square shape. In addition, the rotation shaft 272 of the first pressing member 270 is preferably provided coaxially with an axis forming the center of the dust collecting body 210.

On the other hand, the fixed shaft 282 is protruded inward from one end of the dust collecting body 210, the inside of the fixed shaft 282 hollow 283 penetrating in the axial direction for the assembly of the rotating shaft 272 ) Is formed. A predetermined portion of the rotation shaft 272 is inserted into the hollow 283 from the upper side of the fixed shaft 282.

In detail, the rotating shaft 272 is formed with a stepped portion 272c supported by the upper end of the fixed shaft 282, the image is coupled to the first pressing member 270 based on the stepped portion (272c). The sub shaft 272a is divided into a lower shaft 272b to which a driven gear (to be described later) for allowing the first pressing member to rotate.

In addition to the above configuration, the dust collecting device 200 according to the present embodiment further includes a driving device for rotating the first pressing member 270.

Hereinafter, the driving device will be described in detail.

The driving device 400 is detachably coupled to the dust collecting device 200 at one side, for example, the lower side of the dust collecting device 200, and when the driving device 400 is coupled to the dust collecting device 200. It is connected to the first pressing member 270.

Therefore, when the dust collecting device 200 is separated from the cleaner body 100, the driving device 400 is separated together.

The driving device 400 includes a compression motor 410 for generating a driving force, a driving gear 430 for smoothly transmitting the rotational force of the compression motor 410 to the first pressing member 270, and A motor housing 420 in which the compression motor 410 is accommodated is included.

In detail, the motor housing 420 is coupled to the fastening part 290 formed under the dust collecting body 210 in a state where the compression motor 410 is accommodated in the motor housing 420.

The fastening protrusion 422 is formed at an outer side of the motor housing 420, and a protrusion insertion hole 292 is formed at the fastening portion 290 to selectively insert the fastening protrusion 422.

In addition, the driving gear 430 is coupled to the shaft 412 of the compression motor 410, when the driving device 400 is coupled to the dust collector 200, is coupled to the lower side of the rotary shaft 272. do. At this time, the lower side of the rotation shaft 270 is formed with a gear coupling portion 273 corresponding to the drive gear 430.

In addition, the fastening member 278 is fastened to the rotation shaft 272 and the driving gear 430 above the rotation shaft 272 while the driving gear 430 is coupled to the rotation shaft 272.

Accordingly, when the compression motor 410 is rotated, the drive gear 430 coupled with the compression motor 410 is rotated, and the first pressing member 270 is rotated by the rotation of the drive gear 430. Is rotated.

In addition, a terminal portion 424 connected to the compression motor 410 is formed at a side of the motor housing 420. The terminal unit 424 is connected to the power supply terminal 174 formed in the dust collector mounting unit 170 when the dust collector 200 is mounted on the dust collector mounting unit 170, and thus, from the cleaner body 100. Allow power to be supplied.

That is, in this embodiment, the power is supplied to the compression motor 410 in a state in which the dust collector 200 is mounted on the dust collector mounting unit 170.

Here, the compression motor 410 is preferably a motor capable of forward rotation and reverse rotation. In other words, the compression motor 410 may be a motor capable of bidirectional rotation.

Accordingly, the first pressing member 270 may rotate forward and reverse, and as the first pressing member 270 rotates forward and reverse, the first pressing member 270 may be compressed on both sides of the second pressing member 280. Dust will accumulate.

As such, the synchronous motor may be used as the compression motor 410 in order to enable forward and reverse rotation of the compression motor 410.

The synchronized motor is configured to be capable of forward and reverse rotation by the motor itself, and the rotation of the motor is converted to the other direction when the force applied to the motor is greater than or equal to a predetermined value while the motor is being rotated in one direction. .

At this time, the force applied to the motor is a resistance force (torque: torque) generated when the first pressing member 270 presses dust, and when the resistance force reaches a set value, the direction of rotation of the motor is changed. It is composed.

Since the synchronized motor is generally known in the motor art, a detailed description thereof will be omitted. However, it is one of the technical ideas of the present embodiment that the forward and reverse rotation of the first pressing member 270 is enabled by a synchronous motor.

In addition, the compression motor 410 preferably continuously rotates the first pressing member 270 forward and backward at the same angular speed so that dust can be easily compressed.

On the other hand, the cleaner body 100 is formed with a dust collector mounting portion 170 on which the dust collector 200 is mounted. In addition, the dust collecting device mounting portion 170 is recessed and molded in the mounting groove 172 on which the driving device 400 is mounted in the state where the dust collecting device 200 is mounted. In addition, the seating groove 172 is provided with a power supply terminal 174 selectively connected with the terminal portion 424 of the driving device 400.

6 is a vertical sectional view of the vacuum cleaner according to the first embodiment.

Referring to FIG. 6, the dust collecting device 200 is inclinedly mounted on the cleaner body 100. At this time, when the bottom surface of the dust collecting device 200 is viewed as a reference, the dust collecting device 200 is mounted to be inclined downward from the front of the cleaner body 100 toward the inside.

In addition, when the dust collecting device 200 is mounted on the cleaner body 100, the second pressing member 280 formed inside the dust collecting body 210 may have the cleaner body 100 as shown in FIG. 6. ) And adjacent parts. That is, the separated dust is located at a portion where the first dust starts to accumulate inside the first dust storage unit 214.

Therefore, the dust discharged and dropped from the first cyclone unit 230 is collected at both sides of the second pressing member 280 as the dust collector 200 is inclined. In this case, since the amount of dust in contact with the first pressing member 270 and the second pressing member 280 increases, it is possible to obtain an advantage that the compression efficiency is increased.

Hereinafter, with reference to Figure 6, the operation of the vacuum cleaner and the compression process of the dust according to the embodiment will be described.

In order to perform cleaning, the dust collector 200 is mounted on the dust collector mounting unit 170. When the dust collector 200 is mounted on the dust collector mounting unit 170, the terminal unit 424 of the driving unit 400 is connected to the power supply terminal 174 of the dust collector mounting unit 170. Accordingly, power is supplied from the cleaner body 100 to the driving device 400.

Then, when the suction motor is turned on, suction force is generated by the suction motor. And, the air containing the dust is sucked through the suction nozzle by the generated suction force. In addition, the air sucked through the suction nozzle is introduced into the cleaner body 100 through the main body suction part 110, and the introduced air is introduced into the dust collector 200 through a predetermined flow path.

In detail, the air containing the dust is sucked in the tangential direction of the first cyclone portion 230 through the first air inlet 218 of the dust collecting body 210. In addition, the sucked air falls while turning along the inner circumferential surface of the first cyclone unit 230, and in this process, the air and the dust are separated from each other while receiving different centrifugal forces by the weight difference.

Then, the dust is separated air is filtered through the through hole 262 of the filter member 260, and then to the outside of the dust collector 200 through the discharge hole 251 and the first air outlet 252. Discharged.

On the other hand, the separated dust is introduced into the dust guide flow path 232 in the tangential direction in the process of turning along the inner circumferential surface of the first cyclone portion 230. In addition, the dust introduced into the dust guide flow path 232 flows along the outer circumferential surface of the first cyclone part 230 by switching the flow direction inside the dust guide flow path 232, and discharges the outlet 234. Dropped through and stored in the first dust storage unit 214.

Meanwhile, the air discharged through the first air outlet 252 is introduced into the cleaner body 100. In addition, the air introduced into the cleaner body 100 is introduced into the second cyclone unit 300 through the connection passage 114.

The air is guided in a tangential direction to the inner wall of the second cyclone portion 300 through a second air inlet (not shown) connected to the end of the connection flow passage 114, and the dust flows again while flowing therein. Are separated.

Then, the separated air is introduced into the cleaner body 100, and the suction motor is cut off or discharged to the outside of the cleaner body 100. On the other hand, the separated dust is introduced into the dust collector 200 through the dust inlet 254, and finally stored in the second dust storage unit 216.

As the suction motor is operated to perform the dust separation process, the first pressing member 270 is rotated by the driving device 400 to compress the dust stored in the first dust storage unit 214. do.

In detail, after the suction motor is operated or simultaneously with the operation of the suction motor, power is applied from the cleaner body 100 to the compression motor 410 so that the compression motor 410 is rotated. When the compression motor 410 is rotated, the drive gear 430 is rotated, and the first pressing member 270 is rotated in one direction by the rotation of the drive gear 430 to compress dust. Let's do it.

When the first pressing member 270 compresses dust and the resistance acting on the first pressing member 270 becomes greater than or equal to a predetermined value, the rotation direction of the compression motor 410 is changed in the opposite direction. Accordingly, the first pressing member 270 is rotated in the other direction to compress the dust.

As such, the first pressing member 270 is rotated in both directions to compress the dust stored in the first dust storage unit 214.

The compression motor 410 is stopped while the operation of the suction motor is stopped.

Therefore, according to this embodiment, since the dust can be compressed by the pressing member, the dust collecting capacity of the dust collecting apparatus can be increased. In addition, since the dust is kept in a compressed state in the dust collecting apparatus, the scattering of dust may be prevented in the process of emptying the dust.

In addition, since the driving device is detachably coupled to the dust collecting device, since the driving device may be separated from the dust collecting device when the dust collecting device is cleaned, water may be prevented from entering the driving device.

7 is a vertical cross-sectional view of the dust collecting apparatus according to the second embodiment, and FIG. 8 is a cross-sectional view of II-II 'of FIG.

7 and 8, the driving device 600 according to the present embodiment is coupled to the sidewall of the dust collecting device 500.

The dust collecting apparatus 500 includes a dust collecting body 510 which forms a dust storage unit 511 and is formed in a substantially cylindrical shape, and a pressing member 550 which is coupled to a sidewall of the dust collecting body 510. do.

In detail, the dust collecting body 510 has a mounting rib 512 on which the rotating shaft 552 of the pressing member 550 is mounted to protrude from the side wall toward the center thereof. The seating rib 512 is formed in a substantially semicircular shape, and the seating groove 555 in which the seating rib 512 is accommodated is formed in the rotation shaft 552.

In addition, the axis of the rotation shaft 552 of the pressing member 550 is inclined with the vertical axis of the dust collecting body 510, more specifically orthogonal.

That is, the rotation shaft 552 of the pressing member 550 is provided in the horizontal direction inside the dust collecting body 510. Thus, the pressing member 550 is vertically rotated. In addition, the rotation shaft 552 penetrates through the sidewall of the dust collecting body 510 in a state of being seated on the mounting rib 512.

In addition, a motor shaft 612 of the compression motor 610 to be described later is coupled to the rotation shaft 552 penetrating the sidewall of the dust collecting body 510.

In addition, the pressing member 550 includes a semicircular pressing plate 554. That is, since the dust collecting body 510 is formed in a substantially cylindrical shape, the pressing plate 554 is formed in a semi-circular shape, so that dust is smoothly compressed by the pressing plate 554.

At this time, the shape of the pressure plate 554 may vary according to the horizontal cross-sectional shape of the dust collecting body 510. For example, when the horizontal cross section of the dust collecting body 510 is formed in a square, the pressing plate 554 may also be formed in a square.

In addition, a partition rib 514 for partitioning the dust storage unit 511 is protruded to a bottom surface of the dust collecting body 510. In addition, the partition rib 514 is located below the rotation shaft 552.

The driving device 600 includes a motor housing 620 coupled to the sidewall of the dust collecting body 510 and a compression motor 610 accommodated in the motor housing 620.

When the driving device 600 is coupled to the dust collecting body 510, the compression motor 610 is coupled to the rotation shaft 552. The motor housing 620 is provided with a terminal portion 622 for supplying power to the compression motor 610. Since the idea of supplying power by the terminal unit has been described in the first embodiment, detailed description thereof will be omitted.

The dust compression process in the dust collecting apparatus 500 comprised as mentioned above is demonstrated.

When power is applied to the compression motor 610, the compression motor 610 is rotated in one direction. Then, when the compression motor 610 is rotated, the pressing member 550 connected to the compression motor 610 is rotated in one direction (for example clockwise). Then, the space between the pressing member 550 and the bottom right side of the dust storage unit 511 is narrowed so that the dust stored on the right side of the partition rib 514 is compressed.

When the resistive force acting as the pressing member 550 is equal to or greater than a set value, the compression motor 610 is rotated in the opposite direction, and the pressing member 550 is rotated in the counterclockwise direction. As a result, the space between the pressing member 550 and the bottom left side of the dust storage unit 511 is narrowed, and the dust stored on the left side of the partition rib 514 is compressed.

Here, since the dust storage unit 511 is partitioned by the partition rib 514, the dust stored in the dust storage unit 511 is prevented from being mixed in the process of compressing dust by the pressing member 550. It can be easily understood that it can be.

9 is a vertical sectional view of the dust collecting apparatus according to the third embodiment.

Referring to FIG. 9, the dust collecting apparatus 700 according to the present exemplary embodiment is formed at the center of the dust collecting body 710 and the dust collecting body 710 to form an external dust. The partition 711 may be divided into a separating part 712 and a dust storage part 714, and a cover member 730 coupled to an upper side of the dust collecting body 710.

In addition, the dust storage unit 714 is provided with a pressing member 750 for compressing the dust stored in the dust storage unit 714, the pressing member 750 is coupled to the side wall of the dust collecting body 710 It is connected to the driving device 800.

In detail, an inlet 715 is formed below the partition 711 to allow air to be sucked into the dust separator 712. That is, air is sucked in from the lower side of the dust separator 712. In addition, an air outlet 717 is formed at the center of the bottom of the dust separator 712 to discharge the dust separated air, and an exhaust pipe 716 having a predetermined height is installed at the air outlet 717.

That is, the exhaust pipe 716 is provided to the dust separator 712 in the up and down direction, and the air from which dust is separated is discharged in a direction parallel to the central axis direction of the dust collecting body 710. A discharge passage 718 is formed below the dust separator 712 to move the discharged air.

In addition, the dust separator 712 is provided with a flow guide 719 for spirally wrapping the exhaust pipe 716.

Air sucked by the flow guide 719 to the lower side of the dust separator through the suction port 715 is raised while maintaining the rotational force, and spirally flows toward the cover member 730.

In addition, a movement passage 713 is formed between the partition 711 and the cover member 730 to allow the dust separated by the dust separator 712 to move to the dust storage 714.

On the other hand, a seating rib 720 is formed on the inner circumferential surface of the dust storage unit 714 on which the rotating shaft 752 of the pressing member 750 is seated. In addition, the seating rib 720 is formed in a substantially semi-circular shape, and a seating groove 755 in which the seating rib 720 is accommodated is formed in the rotation shaft 752.

In addition, the axis of the rotation shaft 752 of the pressing member 750 is inclined with the vertical axis of the dust storage unit 714, more specifically orthogonal to.

That is, the rotation shaft 752 of the pressing member 750 is provided in the horizontal direction inside the dust storage unit 714. In addition, the rotation shaft 752 penetrates the sidewall of the dust collecting body 710 in a state of being seated on the mounting rib 720.

The motor shaft 822 of the compression motor 820, which will be described later, is coupled to the rotation shaft 752 that penetrates the sidewall of the dust collecting body 710.

In addition, the pressing member 750 includes a pressing plate 754 having a rectangular plate shape. In addition, a partition rib 721 for partitioning the dust storage part 714 is protruded from a bottom of the dust collecting body 710. The partition rib 721 is provided in parallel with the rotation shaft 752.

The driving device 800 includes a motor housing 810 coupled to the sidewall of the dust collecting body 710 and a compression motor 820 accommodated in the motor housing 810.

When the driving device 800 is coupled to the dust collecting body 710, the compression motor 820 is coupled to the rotation shaft 752. In addition, the motor housing 810 is provided with a terminal portion 812 for supplying power to the compression motor 820. Since the idea that power is supplied by the terminal unit 812 has been described in the first embodiment, detailed description thereof will be omitted.

In addition, the process of compressing the dust in the dust collector 700 is the same as described in the third embodiment, a detailed description thereof will be omitted.

FIG. 10 is a perspective view of the dust collecting apparatus separated from the vacuum cleaner according to the fourth embodiment, FIG. 11 is an exploded perspective view of the dust collecting apparatus according to the fourth embodiment, and FIG. 12 is taken along line III-III ′ of FIG. 10. It is an incision section.

10 to 12, the vacuum cleaner 900 according to the present embodiment is configured to separate and store a cleaner body 910 having a suction motor (not shown) therein and dust contained in sucked air. Dust collector 1000 is included.

In detail, a main body suction part 920 is formed at the front lower end of the cleaner main body 910 to suck air containing dust sucked from the suction nozzle. In addition, a body discharge part 930 through which dust separated air is discharged to the outside is formed at one side of the cleaner body 910.

In addition, a dust collector mounting part 940 on which the dust collector 1000 is mounted is formed above the main body suction part 920, and on one side of the dust collector mounting part 940 through the main body suction part 920. An air outlet 950 is formed to discharge air sucked into the cleaner body 910 to the dust collector 1000.

On the other hand, the dust collector 1000, the dust separation unit 1010 for separating the dust contained in the inhaled air, and is selectively coupled to the dust separation unit 1010 is separated from the dust separation unit 1010 Dust collecting body 1050 is stored, and the upper cover 1030 is coupled to the upper side of the dust separation unit 1010.

In detail, the dust separator 1010 includes a cyclone 1011 having a cylindrical shape that separates the sucked air and dust by the cyclone principle, that is, the air and the dust by the centrifugal force difference.

In addition, an inlet 1012 through which air containing dust is sucked is formed on the cyclone 1011. Here, the inlet 1012 is preferably formed in the tangential direction of the cyclone 1011 in order to generate a cyclone flow in the cyclone 1011.

Meanwhile, a discharge hole 1032 is formed at the center of the upper cover 1030 to discharge air from which dust is separated by the cyclone 1011.

In addition, an exhaust member 1040 is coupled to the lower side of the upper cover 1030. On the outer circumferential surface of the exhaust member 1040, a plurality of through holes 1042 through which dust from the cyclone 1011 is discharged is formed. Therefore, the air that has undergone the dust separation process in the cyclone 1011 is discharged to the outside of the dust collector 1000 through the exhaust hole 1032 through the exhaust member 1040.

In addition, a dust discharge part 1018 through which the separated dust is discharged is formed under the dust separation part 1010.

On the other hand, the dust collecting body 1050 is coupled to the lower side of the dust separation unit 1010. In addition, a dust storage unit 1055 is formed inside the dust collecting body 1050 to store the dust separated from the dust separation unit 1010.

Here, for easy handling of the dust separator 1010 and the dust collecting body 1050, the dust separator 1010 and the dust collecting body 1050 has an upper handle 1013 and a lower handle 1051, respectively. It is provided.

In addition, a hook device is provided in the dust collector 1000 so that the dust collector body 1050 and the dust separator 1010 may be coupled to each other. In detail, a hook hook 1014 is provided at the lower end of the outer circumferential surface of the dust separation unit 1010, and a hook part 1053 is selectively coupled to the hook hook 1014 at the upper end of the outer circumferential surface of the dust collecting body 1050. do.

Meanwhile, the dust collecting apparatus 1000 includes a first pressing member 1060 and a second pressing member 1070 which reduce the volume of dust stored in the dust storage unit 1055 to increase the dust collecting capacity of the dust. It is provided.

In detail, the first pressing member 1060 is coupled to the lower side of the dust separator 1010, and the second pressing member 1070 is formed inside the dust collecting body 1050. In addition, the first pressing member 1060 is rotated by a driving device to be described later to compress the dust on both sides of the second pressing member 1070.

In addition, the driving device is provided inside the dust separation unit 1010 and is connected to the first pressing member 1060. The driving device includes a compression motor 1100 for generating a driving force, and a driving gear 1110 for smoothly transmitting the rotational force of the compression motor 1100 to the first pressing member 1060.

The compression motor 1100 is accommodated in the motor accommodating part 1016 formed under the dust separating part 1010. In addition, the lower side of the dust separator 1010 is shielded by the cover member 1020 while the compression motor 1100 is accommodated in the motor accommodating part 1016.

In addition, the cover member 1020 is detachably coupled to the lower side of the dust separation unit 1010 to allow repair or replacement of the compression motor 1100.

Here, the cover member 1020 is formed with an opening 1022 so that dust moving the dust discharge portion 1018 can fall to the dust collecting body 1050 side.

Meanwhile, the driving gear 1110 is coupled to the motor shaft 1102 of the compression motor 1100 and the rotation shaft 1062 of the first pressing member 1060.

At this time, the lower side of the rotation shaft 1062 is formed with a gear coupling portion 1063 corresponding to the drive gear 1110. In addition, the fastening member 1064 is fastened to the rotation shaft 1062 and the driving gear 1110 under the rotation shaft 1062 in a state in which the driving gear 1110 is coupled to the rotation shaft 1062.

In addition, a terminal portion 1124 connected by the compression motor 1100 and the connection portion 1122 is formed at a side surface of the dust separator 1010. When the dust collector 1000 is mounted on the dust collector mounting unit 940, the terminal unit 1124 is connected to a power supply terminal 942 formed in the dust collector mounting unit 940 and is connected to the vacuum cleaner body 910. Allow power to be supplied. Here, the process of compressing the dust in the dust collector 1000 is the same as described in the previous embodiment, a detailed description thereof will be omitted.

As such, when the compression motor 1100 is provided to the dust separation unit 1010, the weight of the dust collecting body becomes light, so that the user can easily discharge the dust stored in the dust collecting body.

Various embodiments proposed above are characterized in that a driving device is provided in the dust collecting apparatus to compress the dust stored in the dust storage unit. Therefore, it is noted that the dust separation method in the dust separation unit and the internal structure of the dust collector are not limited to the proposed description.

According to the embodiment as proposed, since the dust stored in the dust collector is compressed by the pressing member to minimize the volume, there is an effect that the capacity of the dust stored in the dust collector is maximized.

In addition, as the dust collecting capacity of the dust collecting device is maximized by the compression action of the pressing member, the user has to remove the trouble of frequently emptying the dust stored in the dust collecting device.

In addition, since the dust is kept in a compressed state in the dust collector, there is an effect of preventing the scattering of dust during the emptying process of the dust.

In addition, since the driving device for driving the pressing member is detachably coupled to the dust collecting device, the driving device can be separated when the dust collecting device is cleaned, thereby preventing water from flowing into the driving device. .

In addition, since the driving device can be separated from the dust collecting device, the driving device can be easily replaced or repaired.

Claims (6)

A dust separator for separating dust in the air; A dust collecting body in which a dust storage unit for storing dust separated from the dust separation unit is formed; A pressurizing member compressing dust stored in the dust storage unit and movable in the dust storage unit; A driving device detachably coupled to the dust collecting body, the driving device including a compression motor rotatable in both directions and a motor housing in which the compression motor is accommodated; A fastening part provided in the dust collecting body and coupled to the motor housing; A cleaner body into which air discharged from the dust separator is introduced; A mounting part formed on the cleaner body and detachably mounted to the dust collecting body, The mounting portion is provided with a recessed groove for mounting the drive device, The motor housing is coupled to the outer wall of the dust collecting body, A terminal portion is formed in the motor housing, The seating groove of the mounting portion is provided with a power supply terminal for contacting the terminal portion, And when the terminal part contacts the power supply terminal, power is supplied from the cleaner body to the compression motor. delete delete delete delete delete

Images