KR100912316B1 - Vacuum cleaner - Google Patents

Abstract

The present invention 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 invention for achieving the above object, the cleaner body; A dust collecting device detachable from the cleaner body and having a dust storage unit formed therein; At least one pressing member movably provided in the dust storage unit to reduce a volume of dust stored in the dust storage unit; A drive motor provided in the cleaner body; A drive gear for transmitting power of the drive motor; A shaft coupled to the rotating shaft of the pressing member is provided, and includes a driven gear for transmitting the driving force transmitted from the driving gear to the pressing member, the coupling surface to which the rotating shaft of the pressing member and the shaft of the gear are coupled It is formed in a corresponding shape, characterized in that the horizontal cross-sectional shape of each coupling surface is formed in each non-circular.

According to the present invention as described above, since the dust stored in the dust collector is compressed by the pressing member to minimize the volume thereof, there is an effect of maximizing the dust collection capacity of the dust stored in the dust collector.

Dust Collector, Dust Compression

Description

Vacuum cleaner {Vacuum cleaner}

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

Figure 2 is a perspective view of a state in which the dust collector is separated from the vacuum cleaner.

3 is a perspective view of a dust collecting device according to the present invention.

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

5 is a perspective view of a first pressing member according to the present invention;

Figure 6 is a bottom perspective view of the dust collecting device according to the present invention.

FIG. 7 is a cross-sectional view taken along the line II-II ′ of FIG. 4.

8 is a perspective view of a dust collecting device mounting portion according to the present invention.

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

100: main body 170: dust collector mounting portion

200: dust collector 270: first pressing member

280: second pressing member 410: driven gear

420: drive gear

The present invention 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.

In general, a vacuum cleaner is a device that sucks air containing dust by using a vacuum pressure generated by a vacuum motor mounted inside the body, and then filters the dust inside the body.

The vacuum cleaner may include a suction nozzle for sucking air containing dust, a cleaner body in communication with the suction nozzle, an extension pipe for guiding air sucked from the suction nozzle toward the cleaner body, and air passing through the extension pipe. A connector is connected to the cleaner body.

Here, a nozzle suction port having a predetermined size is formed at 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, a driving unit for generating an air suction force to suck the outside air containing dust to the suction nozzle is provided.

In addition, the dust collector is detachably mounted to the cleaner body to separate and store dust. The dust collector performs a function of separating and storing dust contained in the air sucked from the suction nozzle.

In detail, the dust collecting apparatus includes a dust collecting body, an inlet for allowing air to be sucked into the dust collecting body, a cyclone portion for separating dust from the air sucked into the dust collecting body, and dust separated from the cyclone portion. The dust storage unit and a discharge port through which the dust is separated from the cyclone portion is discharged.

Meanwhile, the dust stored in the lower space of the dust collecting body, that is, the dust storage unit, continuously rotates along the inner circumferential surface of the dust collecting body by the rotational flow inside the dust collecting body while the vacuum cleaner is operating.

When the operation of the vacuum cleaner is stopped, the vacuum cleaner sinks to the bottom of the dust collecting body and is stored in a low density state.

Therefore, in the conventional dust collecting apparatus, when a predetermined amount or more of dust is stored in the dust collecting unit while the vacuum cleaner is operating, the dust rises while rotating along the inner wall of the dust collecting body, and is formed in the upper space of the dust collecting body. There is a problem in that the cyclone portion is violated, and thus the unseparated dust is discharged to the discharge port by piggybacking on the discharge airflow, so that dust collection performance is reduced.

In addition, when the operation of the vacuum cleaner is stopped, the dust sinks to the bottom of the dust collecting body as it is stored in a low density state. That is, since dust inside the dust collecting body occupies a volume too large for its weight, there is an inconvenience of frequently emptying the dust collecting body in order to maintain dust collecting performance.

Therefore, in recent years, in order to improve the convenience of cleaner use, efforts have been made to maximize the capacity of dust collected in the dust collecting body and to improve dust collecting performance.

The present invention has been made to solve the above problems, and an object of the present invention is to propose a vacuum cleaner to increase the dust collecting capacity of the dust collecting apparatus.

In addition, it is an object of the present invention to propose a vacuum cleaner that allows the dust stored in the dust collector to be automatically compressed to increase the dust collection capacity.

Vacuum cleaner according to the present invention for achieving the object as described above, the cleaner body; A dust collecting device detachable from the cleaner body and having a dust storage unit formed therein; At least one pressing member movably provided in the dust storage unit to reduce a volume of dust stored in the dust storage unit; A drive motor provided in the cleaner body; A drive gear for transmitting power of the drive motor; A shaft coupled to the rotating shaft of the pressing member is provided, and includes a driven gear for transmitting the driving force transmitted from the driving gear to the pressing member, the coupling surface to which the rotating shaft of the pressing member and the shaft of the gear are coupled It is formed in a corresponding shape, characterized in that the horizontal cross-sectional shape of each coupling surface is formed in each non-circular.

According to another aspect of the present invention, a vacuum cleaner includes a cleaner body; A dust separator for separating dust from air introduced into the cleaner body; A dust collecting body detachably coupled to the cleaner body and having a dust storage unit configured to store dust; A fixing member fixed inside the dust collecting body; A rotatable member that is movable inside the dust collecting body and reduces a volume of dust stored in the dust storage unit by interaction with the fixing member; A drive motor provided in the cleaner body; A gear coupled to the rotating member outside the dust collecting body and transmitting a driving force of the driving motor to the rotating member; A fixed shaft protruding in the dust collecting body is included, the rotating shaft of the rotating member is coupled to the fixed shaft is rotated, the rotating member has an interference prevention groove for preventing interference in the process of coupling with the fixed shaft It is characterized by being formed.

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Hereinafter, with reference to the drawings will be described a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the proposed embodiment, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is a perspective view of a vacuum cleaner according to the present invention, Figure 2 is a perspective view of the dust collector is separated from the vacuum cleaner, Figure 3 is a perspective view of the dust collector according to the present invention.

1 to 3, the vacuum cleaner 10 according to the present invention includes a cleaner body 100 provided with a suction motor (not shown) for generating a suction force therein and sucked into the cleaner body 100. And dust separation means for separating the dust contained in the air.

Although not shown, a suction nozzle for sucking air containing dust 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 is sucked is formed at the front lower end of the cleaner main body 100, and at one side of the cleaner main body 100, dust is separated from the air. The main body discharge part (not shown) 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.

In addition, the rear side of the cleaner body 100 is coupled with a guide cover 160 for guiding the air separated by the dust separation means to enter the cleaner body 100.

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, in order to allow the dust collecting apparatus 200 to be detachable from the cleaner body 100, a detachable lever 142 is provided on the handle 140 of the cleaner body 100, and the dust collecting apparatus 200 is provided. ) Is formed with a locking end 256 for engaging with the detachable lever 142.

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 212 is formed to allow air to enter from 130.

At this time, the first air inlet 212 is preferably formed in the tangential direction of the dust collector 200 in order to generate a cyclone flow in the dust collector 200.

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.

As described above, by arranging the second cyclone unit 300 lying on the cleaner main body 100, the space utilization of the vacuum cleaner requiring miniaturization may be improved in the arrangement relationship with the vacuum motor or the like. Can be.

In addition, as the second cyclone unit 300 is separated from the dust collecting device 200 and provided in the cleaner main body 100, the structure of the dust collecting device 200 is simplified, and the weight is light. The dust collector 200 can be handled with little force.

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.

In other words, in the present embodiment, the second cyclone part 300 is separated from the dust collecting device 200 and is configured in the cleaner body 100, and the dust separated from the second cyclone part 300. Is configured to be stored in the dust collector 200.

Here, the second cyclone unit 300 is preferably disposed to be inclined downward toward the dust collector 200 so that the separated dust can be easily moved to the dust collector 200.

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, it is preferable that a configuration for reducing the volume of dust stored in the dust collecting body 210 is added to the dust collecting device (200).

The operation of the vacuum cleaner 10 will be described briefly by the above configuration.

First, when power is applied to the vacuum cleaner 10 and the cleaner body 100 operates, suction power is generated by a vacuum motor provided therein. In addition, the air containing the dust sucked by the suction nozzle by the suction force is sucked into the dust collector 200 along a predetermined flow path formed in the connection pipe and the cleaner body 100.

Then, when the air containing the dust is sucked into the dust collector 200, the dust is primarily separated by the first cyclone portion. Then, the separated dust is stored in the dust collecting body 210. On the other hand, the dust is separated air is discharged from the dust collector 200 is introduced into the cleaner main body 100, the inflow into the second cyclone unit 300 by the connection flow path 114 provided in the cleaner main body (100) do.

And, the air introduced into the second cyclone unit 300 is again dust is separated, the separated dust is introduced into the dust collector 200 and stored, the dust separated air is inside the cleaner body 100 After flowing along a predetermined flow path of the finally discharged to the outside through the body discharge.

Hereinafter, referring to FIGS. 4 and 8, a vacuum cleaner having a dust collecting device according to the present invention having a maximum dust collecting capacity will be described.

4 is a cross-sectional view taken along the line II ′ of FIG. 3, and FIG. 5 is a perspective view of a first pressing member according to the present invention.

4 and 5, the dust collecting apparatus 200 according to the present invention has a dust collecting body 210 forming an external shape, and is selectively accommodated in the dust collecting body 210 to separate dust from sucked air. 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.

As such, as the second dust storage unit 216 is provided outside the first dust storage unit 214, the size of the first dust storage unit 214 may be maximized, such that the first dust There is an advantage that the dust collecting capacity of the storage unit 214 is maximized.

In addition, the first wall 211 is formed with a step 219 supporting the lower end of the first cyclone portion 230 accommodated therein in the circumferential direction. Therefore, the upper part of the first dust storage unit 214 has a larger diameter than the lower part based on the step 219.

On the other hand, the dust collecting body 210 has an upper end opened so that a user can turn over the dust collecting body 210 to discharge dust, and the cover member 250 is detachable on the upper part of the dust collecting body 210. 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.

In this embodiment, the first cyclone portion 230 is coupled to the cover member 250, but the first cyclone portion 230 and the cover member 250 are integrally formed. It can be revealed.

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.

Therefore, in order to discharge the dust stored in the first dust storage unit 214 and the second dust storage unit 216 to the outside, the cover member 250 to which the first cyclone unit 230 is coupled When the separation from the dust collecting body 210, the upper end of the dust collecting body 210 is completely opened. And, when the user flips the dust collecting body 210, the dust is easily discharged.

In this case, in order to empty the dust collecting body 210, the user separates the cover member 250 from the dust collecting body 210 in a trash can or outdoors, thereby preventing re-contamination of the room.

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, thereby reducing the density of the dust stored in the dust collecting body 210. The maximum dust collecting capacity of the dust collecting body 210 is increased.

Hereinafter, for convenience of description, one of the pair of pressing members 270 and 280 is referred to as a first pressing member 270 and the other as 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. ) Is rotated 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 fixed 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.

In addition, in order to prevent the falling of the dust stored in the first dust storage unit 214 through the outlet 234 by the second pressing member 280, the second pressing member 280 is the It is preferably located opposite the outlet 234 with respect to the central axis of the dust collecting body (210).

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.

In addition, a plurality of pressing protrusions 276 may be formed on an outer surface of the first pressing member 270 that is rotated in the dust collecting body 210. The pressing protrusion 266 allows the first pressing member 270 to move toward the second pressing member 280 to compress the dust, thereby effectively compressing the dust.

In addition, an upper end of the first pressing member 270 may be formed with a cutout 274 (Chamfer) cut at a predetermined angle. The cutout 274 is provided with a space between the outlet 234 and the first pressing member 270 when the upper end of the first pressing member 270 is positioned below the outlet 234. In this case, the dust is easily discharged through the outlet 234.

That is, the cutout 274 serves to prevent dust discharged through the outlet 234 from interfering with the first pressing member 270.

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). It is divided into a lower shaft 272b to which the auxiliary shaft 272a and the driven gear (to be described later) for allowing the first pressing member 170 to rotate.

In addition, the first pressing member 270 prevents interference between the first pressing member 270 and the fixed shaft 282 while the lower shaft 272b is coupled to the fixed shaft 282. An interference prevention groove 275 is formed. That is, a predetermined interval is formed between the lower shaft 272b and the first pressing member 270.

In addition to the above configuration, the vacuum cleaner according to the present invention further includes a driving device selectively connected to the rotation shaft 272 of the first pressing member 270 to rotate the first pressing member 270.

Hereinafter, the coupling relationship between the dust collecting device 200 and the driving device will be described in detail with reference to FIGS. 6 to 8.

6 is a bottom perspective view of the dust collecting apparatus according to the present invention, FIG. 7 is a cross-sectional view taken along the line II-II ′ of FIG. 4, and FIG. 8 is a perspective view of the dust collecting unit mounting portion according to the present invention.

6 to 8, a driving apparatus for driving the first pressing member 270 includes a driving motor (not shown) for generating a driving force, and a driving force of the driving motor for the first pressing member 270. It includes a power transmission unit 410, 420 to transmit.

In detail, the power transmission units 410 and 420 may be driven gears 410 coupled to the rotation shaft 272 of the first pressing member 270, and drive gears 420 transferring power to the driven gears 410. ) Is included.

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

Therefore, when the drive motor is rotated, the drive gear 420 coupled with the drive motor is rotated, the rotational force of the drive motor is transmitted to the driven gear 410 by the drive gear 420 to the driven The gear 410 is rotated, and finally, the first pressing member 270 is rotated by the rotation of the driven gear 410.

In detail, the driven gear 410 is coupled to the rotation shaft 272 of the first pressing member 270 at the lower side of the dust collecting body 210.

As the driven gear 410 is coupled to the lower side of the dust collecting body 210, the driven gear 410 is exposed to the outside of the dust collecting body 210. Accordingly, as the dust collecting device 200 is mounted on the dust collecting device mounting unit 170, the driven gear 410 is engaged with the driving gear 420. Detailed description thereof will be described later.

When the driven gear 410 is rotated, the inner circumferential surface of the rotating shaft 272 and the driven gear 270 may be simultaneously rotated together with the first pressing member 270 without turning. The outer circumferential surface horizontal cross-sectional shape of the gear shaft 414 of 410 is preferably polygonal.

Here, FIG. 7 shows that the horizontal section of the rotation shaft 272 and the gear shaft 414 of the driven gear 410 is formed in an octagonal shape.

However, the horizontal cross-sectional shape of the rotation shaft 272 and the gear shaft 414 of the driven gear 410 is not limited thereto, and may have various shapes. That is, the horizontal cross-sectional shape of the rotation shaft 272 and the gear shaft 414 of the driven gear 410 is formed in a non-circular shape, so that the first pressing member 270 smoothly rotates when the driven gear 410 is rotated. It is preferred that it can be rotated.

In addition, the fastening member 278 may be fastened on the upper side of the rotating shaft 272 while the driven gear 410 is coupled to the rotating shaft 272. Therefore, not only the driven gear 410 and the rotation shaft 272 are firmly coupled, but also the phenomenon in which the driven gear 410 is lost can be further prevented.

On the other hand, the drive motor is provided on the lower side of the dust collector mounting portion 170, the drive gear 420 is coupled to the rotation shaft of the drive motor is provided on the bottom surface of the dust collector mounting portion 170.

In addition, a portion of the outer circumferential surface of the drive gear 420 is exposed to the outside from the bottom of the dust collector mounting portion 170. To this end, it is preferable that a motor accommodating part (not shown) in which the driving motor is installed is formed below the bottom of the dust collecting device mounting part 170. In addition, an opening 173 for exposing a portion of the outer circumferential surface of the drive gear 420 to the dust collector mounting unit 170 is formed at a substantially central portion of the bottom of the dust collector mounting unit 170.

As the driven gear 410 is exposed to the dust collector mounting unit 170, when the dust collector 200 is mounted on the dust collector mounting unit 170, the driven gear 410 is driven by the driving gear 420. ) Is engaged.

Here, the drive motor is preferably a motor capable of forward rotation and reverse rotation. In other words, the driving motor 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, in order to enable forward and reverse rotation of the drive motor, a synchronous motor may be used as the drive motor.

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

At this time, the force applied to the motor is a resistance force (torque) generated when the first pressing member 270 presses the dust, and when the resistance force reaches a set value, the rotation of the motor is directed. It is configured to be converted.

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 invention to enable forward and reverse rotation of the driving motor by the synchro motor.

In addition, even when the first pressing member 270 rotates to reach a peak that can no longer rotate while compressing the dust, the first pressing member 270 may continuously press the dust for a predetermined time. Do.

Here, the peak that the first pressing member 270 cannot rotate refers to when the resistance reaches a set value.

When the resistance reaches the set value, the power for rotating the first pressing member 270, that is, the power applied to the driving motor is cut off for a predetermined time, so that the first pressing member 270 is stopped. The dust is compressed in the stopped state, and when the predetermined time passes, the first pressurizing member 270 is moved by applying power to the driving motor again.

At this time, since the resistance time when the power applied to the drive motor reaches the set value, when the drive motor is driven again, the rotation direction of the drive motor will be the opposite direction before the power cut off.

In addition, the drive motor preferably continuously rotates the first pressing member 270 forward / reversely at the same angular speed so that dust can be easily compressed.

In addition, when a dust or more of a predetermined amount of dust is collected inside the dust collecting body 210, it is preferable to display the emptying time of the dust collecting body 210 to the user in order to prevent deterioration of dust collection performance and overload of the motor. .

To this end, a display unit (not shown) is provided on the cleaner body 100, the dust collecting device 200, or the handle (not shown), and dust or more is stored in the dust collecting body 210 to store a predetermined amount of dust. 1 When the rotation range of the pressing member 270 is less than a predetermined angle, the emptying time of the dust collecting body 210 is displayed to the user.

On the other hand, the lower side of the dust collecting body 210 is formed with a guide rib 290 for guiding the mounting of the dust collecting device 200 to the cleaner body 100, the dust collector mounting portion 170, the guide rib ( An insertion groove 172 into which the 290 is inserted is formed.

The guide rib 290 is provided in a "C" shape on the outer side of the driven gear 410 to surround a portion of the driven gear 410. Accordingly, the guide rib 290 also serves to protect the driven gear 410.

Here, when the dust collecting device 200 is mounted on the dust collecting device mounting unit 170, the driven gear 410 and the driving gear 420 should be coupled to each other. For this reason, the guide rib 290 is formed so that a portion of the driven gear 410 is exposed to the outside.

In addition, the dust collecting device mounting unit 170 has a removal prevention hole 174 that prevents the dust collecting device 200 from being removed to the front of the cleaner body 10 while the dust collecting device 200 is seated on the dust collecting device mounting unit 170. The guide rib 290 is formed with a stripping prevention protrusion 294 inserted into the stripping prevention hole.

Therefore, even when the dust collecting device 200 is pulled forward by the dust collecting device 200 seated on the dust collecting device mounting portion 170 by the stripping prevention hole 174, the anti-separation protrusion 294 Is caught by the removal preventing hole 174 to prevent the removal of the dust collector 200.

In addition, the dust collecting device mounting portion 170 is formed with a seating portion 176 for guiding the mounting of the guide rib 290, the seating groove of the shape corresponding to the seating portion 290 in the guide rib 290. 295 is formed.

The dust collecting device 200 may be easily mounted to the dust collecting device mounting unit 170 by the seating unit 290 and the mounting groove 295, and the dust collecting device 200 may be mounted on the dust collecting device mounting unit ( Rocking is prevented in the state of mounting at 170).

Hereinafter, the operation of the vacuum cleaner constituting the above-described configuration will be described.

First, when power is applied to the suction motor of the vacuum cleaner 10, suction force is generated by the suction motor, and air containing dust is sucked into the suction nozzle by the 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 dust-containing air is sucked in the tangential direction of the first cyclone part 230 through the first air inlet 212 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.

In addition, 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 changing the flow direction inside the dust guide flow path 232, and the discharge port 234. Falling downward through the first dust storage unit 214 is stored.

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 the second air inlet 302 connected to the end of the connecting passage 114, and the dust flows again while flowing therein. Are separated.

In addition, the air from which the dust is separated again flows into the cleaner body 100. In addition, the air introduced into the cleaner body 100 is discharged to the outside through the body discharge part of the rear side of the cleaner body 100 through the suction motor.

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 dust in the air is separated and dust is stored in the dust storage unit as described above, the pair of pressing members 270 and 280 compress the dust stored in the first dust storage unit 114.

In detail, when the drive motor is rotated in one direction, the rotational power of the drive motor is transmitted to the driven gear 410 through the drive gear 420, so that the driven gear 410 is rotated in one direction. In addition, the rotation shaft 272 and the first pressing member 270 are rotated by the rotation of the driven gear 410.

As described above, when the first pressing member 270 is rotated in one direction, the first pressing member 270 removes dust between the first pressing member 270 and the second pressing member 280 from the second pressing member 270. The dust is compressed by pushing toward one side of the pressing member 280. The rotation of the first pressing member 270 is continued until the resistance generated in the process of pressing the dust reaches a set value.

When the resistance reaches a predetermined value or more, the power applied to the driving motor is cut off and the first pressing member 270 is stopped in the state in which the dust is compressed.

Then, the first pressing member 270 presses the dust for a predetermined time at the stop position. When the predetermined time elapses, the driving motor is driven again to rotate the first pressing member 270.

Here, since the first pressing member 270 is stopped in the state where the resistance force reaches a set value, the rotation direction is converted and rotated in the other direction.

In addition, when the first pressing member 270 is rotated in the other direction, the first pressing member 270 presses the dust between the first pressing member 270 and the second pressing member 280 to the second pressing member. The dust is compressed by pushing toward the other side of the member 280.

When the resistance applied to the first pressing member 270 reaches a predetermined value or more during the rotation of the first pressing member 270, the power applied to the driving motor is cut off, thereby the first pressing member 270. ) Is stopped while the dust is compressed.

Then, the first pressing member 270 presses the dust for a predetermined time at the stop position. When the predetermined time passes, the driving motor is driven again to rotate the first pressing member 270 in the opposite direction.

As described above, the compressing action is repeatedly performed until the rotation range of the first pressing member 270 is equal to or less than a predetermined angle. When the cleaner is stopped by the user in this process, the dust compressing process is terminated.

Meanwhile, in order to empty the dust stored in the dust collecting body 210, the user separates the dust collecting device 200 from the cleaner body 100.

In addition, the cover member 250 to which the first cyclone unit 230 is coupled is separated from the dust collector 200. Then, the dust collecting body 210 is reversed to empty the dust.

According to the present invention as proposed has the following effects.

First, since the dust stored in the dust collector is compressed by a pair of pressing members to minimize the volume thereof, there is an effect of maximizing the dust collection capacity of the dust stored in the dust collector.

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

Third, as the dust collected in the dust collecting apparatus maintains the compressed state even when the operation of the vacuum cleaner is stopped, the dust stored in the dust collecting unit is easily discharged to the outside of the dust collecting apparatus when the dust is empty.

Fourth, as the horizontal sectional shape of the outer circumferential surface of the driven gear for receiving the driving force from the inner peripheral surface of the rotating shaft formed on the first pressing member and the driving motor to rotate the first pressing member has a non-circular shape, Since it can be rotated together with the first pressing member, the dust compression reliability is improved.

Claims (11)

A cleaner body; A dust collecting device detachable from the cleaner body and having a dust storage unit formed therein; At least one pressing member movably provided in the dust storage unit to reduce a volume of dust stored in the dust storage unit; A drive motor provided in the cleaner body; A drive gear for transmitting power of the drive motor; A shaft coupled to the rotation shaft of the pressing member is provided, and includes a driven gear for transmitting a driving force transmitted from the driving gear to the pressing member, The coupling surface to which the rotating shaft of the pressing member and the shaft of the gear are coupled to each other is formed in a shape corresponding to each other, the horizontal cross-sectional shape of each coupling surface is formed in a non-circular vacuum cleaner. delete The method of claim 1, The inner circumferential surface horizontal cross-sectional shape of the rotation shaft of the pressing member is formed in a non-circular shape, the vacuum cleaner is formed in a non-circular shape in the horizontal circumferential shape of the outer peripheral surface of the shaft of the driven gear. The method of claim 3, wherein Horizontal cross-sectional shape of the inner peripheral surface of the rotating shaft is a polygon vacuum cleaner. delete delete delete delete delete A cleaner body; A dust separator for separating dust from air introduced into the cleaner body; A dust collecting body detachably coupled to the cleaner body and having a dust storage unit configured to store dust; A fixing member fixed inside the dust collecting body; A rotatable member that is movable inside the dust collecting body and reduces a volume of dust stored in the dust storage unit by interaction with the fixing member; A drive motor provided in the cleaner body; A gear coupled to the rotating member outside the dust collecting body and transmitting a driving force of the driving motor to the rotating member; It includes a fixed shaft protruding in the interior of the dust collecting body, The rotary shaft of the rotary member is coupled to the fixed shaft is rotated, the rotary member, the vacuum cleaner is formed with an interference prevention groove to prevent interference in the process of coupling with the fixed shaft. delete

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