KR100849548B1 - 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 increased.

Vacuum cleaner according to the embodiment comprises a dust separator; A dust storage unit storing dust separated from the dust separation unit; A compression unit connecting the dust separation unit and the dust storage unit; A compression member provided to the compression unit to guide the separated dust to be moved to the dust storage unit, and compressing the dust during the movement of the dust; And a driving device for driving the compression member. According to this embodiment, since the separated dust is compressed by the compression member and stored in the dust storage unit, there is an effect that the capacity of the dust stored in the dust collector is maximized.

Description

Vacuum cleaner {Vacuum cleaner}

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

2 is a cross-sectional view taken along the line II ′ of FIG. 1.

3 is a cross-sectional view showing a state in which the dust collecting apparatus according to the first embodiment is mounted on the dust collecting unit mounting portion.

4 is a view showing an air flow and dust compression process inside the dust collecting apparatus according to the first embodiment.

5 is a vertical sectional view of the dust collecting apparatus according to the second embodiment.

6 is a cross-sectional view showing an upper structure of a dust collecting unit mounting unit according to the second embodiment.

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

Fig. 8 is a block diagram showing a control structure of a drive device according to the third embodiment.

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

10: cleaner body 100: dust collector

112: dust separation unit 113: compression unit

114: dust storage unit 160: compression member

210: compression motor 220: drive gear

230: driven gear

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 increased.

In general, a vacuum cleaner is a device that sucks air containing dust by using a vacuum pressure generated by a suction 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, there is provided a suction device for generating an air suction force so that the outside air containing dust to the suction nozzle.

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.

When the vacuum cleaner is stopped while the dust separation process is performed in the dust collector, the separated dust is stored in a low density state in the dust storage unit.

According to the conventional dust collector, since the dust stored in the dust storage unit occupies a volume too large for its weight, there is an inconvenience of frequently emptying the dust of the dust collector in order to maintain dust collection performance.

Therefore, in recent years, in order to improve the convenience of using a cleaner, efforts have been made to maximize the capacity of dust collected in the dust collector and at the same time improve dust collection performance.

The present embodiment has been proposed to solve the above problems, and an object of the present invention is to propose a vacuum cleaner for increasing the dust collecting capacity of the dust collecting apparatus by compressing the dust stored in the dust collecting apparatus.

In addition, an embodiment of the present invention aims to propose a vacuum cleaner in which dust is prevented from being discharged in a process of discharging dust stored in a dust collecting apparatus.

Vacuum cleaner according to an embodiment for achieving the object as described above is a dust separation unit; A dust storage unit storing dust separated from the dust separation unit; A compression unit connecting the dust separation unit and the dust storage unit; A compression member provided to the compression unit to guide the separated dust to be moved to the dust storage unit, and compressing the dust during the movement of the dust; And a driving device for driving the compression member.

Vacuum cleaner according to an embodiment according to another aspect has a dust collecting body having a compression portion is reduced in diameter from the upper side to the lower side; A compression member provided in the compression unit; A compression rib formed in a spiral shape on an outer side of the compression member; And a driving device for rotating the compression member, wherein the dust separated from the dust collecting body passes through the compression unit, and the dust is compressed by the inner circumferential surface of the compression unit and the compression rib while the separated dust passes through the compression unit. This is characterized in that it is performed.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a state in which a dust collecting apparatus is separated from a vacuum cleaner according to a first embodiment.

Referring to FIG. 1, the vacuum cleaner 1 according to the present embodiment includes a cleaner main body 10 having a suction motor (not shown) that generates suction force therein, and an air suctioned by the cleaner main body 10. Dust collector 100 for separating and storing the included dust is included.

In addition, the vacuum cleaner 10 includes a suction nozzle 14 for sucking air containing dust, a handle 11 for allowing a user to operate an operation of the vacuum cleaner 1, and the suction. An extension tube 12 connecting the nozzle 14 and the handle 11 and a connection hose 13 connecting the handle 11 and the cleaner body 10 are included.

In this embodiment, a detailed description of the basic configuration of the suction nozzle 14, extension tube 12, handle 11 and the connection hose 13 will be omitted.

In detail, a main body suction part 17 is formed at the front lower end of the cleaner main body 10 to suck air containing dust sucked from the suction nozzle 14. Therefore, the air containing the dust sucked through the main body suction unit 17 is introduced into the dust collector 100 to undergo a dust separation process.

In addition, the cleaner body 10 is provided with a dust collecting device mounting portion 16 on which the dust collecting device 100 is seated. In addition, the dust collecting device mounting unit 16 is formed with a guide unit 19 for guiding the mounting of the dust collecting device 100.

On the other hand, the dust collector 100 allows the dust to be separated from the air by the cyclone method.

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

2 is a cross-sectional view taken along line II ′ of FIG. 1, and FIG. 3 is a cross-sectional view illustrating a state in which a dust collecting device according to a first embodiment is mounted on a dust collecting unit mounting portion.

2 and 3, the dust collecting apparatus 100 according to the present embodiment includes a dust collecting body 110 forming an external shape, an upper cover 120 coupled to an upper side of the dust collecting body 110, and The lower cover 130 is coupled to the lower side of the dust collecting body 110 to allow dust to be discharged to the outside.

In addition, a filter member 140 for filtering dust from air introduced into the dust collecting body 110 and a compression member for compressing the dust separated inside the dust collecting body 110 are compressed in the dust collecting body 110. 160 is provided.

In detail, the dust collecting body 110, the dust separating portion 112 is formed in a cylindrical shape, the compression unit 113 is formed on the lower side of the dust separating portion 112, the diameter is reduced toward the lower side 113 And a dust storage unit 114 formed in a cylindrical shape at the lower side of the compression unit 113.

An upper side of the dust separation unit 112 is formed with an inlet 111 for inhaling air containing dust. The suction port 111 is connected to the dust separation unit 112 such that air sucked into the dust separation unit 112 through the suction hole 111 may helically flow in the dust separation unit 112. It is formed in the tangential direction.

In addition, a filter member 140 is provided inside the dust separator 112 to filter the air that has undergone the dust separation process. In addition, the filter member 140 is coupled to the lower side of the upper cover 120. In addition, a plurality of through holes 142 are formed in the filter member 140.

Accordingly, the air that has undergone the dust separation process in the dust separation unit 112 is filtered while passing through the through hole 142, and then flows into the filter member 140.

On the other hand, one side of the dust storage unit 114 is formed with a discharge hole 152 for discharging the air through the dust separation process, the discharge pipe 150 for guiding the discharge of air to the inside of the discharge hole 152 Is formed. The discharge pipe 150 extends in the horizontal direction from the discharge hole 152 toward the center of the dust storage unit 114 and is bent upward from the center of the dust storage unit 114. Thus, the discharge pipe 150 has a vertical cross-section is formed in a substantially "L" shape.

In addition, the lower cover 130 is coupled to the lower side of the dust collecting body 110 to shield the dust storage unit 114. In this case, the lower cover 130 may be rotatably coupled to the dust collecting body 110 or may be detachably coupled to the dust collecting body 110.

On the other hand, the compression unit 113 is formed so that the diameter becomes smaller toward the lower side as described above, the vertical cross section is formed in a truncated conical shape. In addition, the compression member 113 is provided with a compression member 160 that is rotated by a driving device to be described later.

In detail, the compression member 160 includes a rotating member 161 formed in a hollow cylindrical shape, a compression rib 162 formed in a spiral shape on the outside of the rotating member 161, and the rotating member 161. Rotating shaft 164 is formed on the upper side of the.

In addition, the compression rib 162 extends in a spiral shape from the upper side to the lower side of the rotating member 161, and the width thereof decreases toward the lower side. That is, since the compression portion 113 is smaller toward the lower side, the compression rib 162 is also formed to be smaller in width toward the lower side. At this time, the pitch of the compression rib 162 may also be formed so as to become smaller toward the lower side.

Therefore, when the rotating member 161 is rotated, the dust separated from the dust separation unit 112 is moved downward along the compression rib 162. That is, the compression rib 162 may also serve to guide the separated dust to move downward.

Here, the diameter of the compressed portion 113 becomes smaller toward the lower side, and the width of the compression rib 162 is also formed to become smaller toward the lower side, the lower the lower portion of the compression portion 113 of the separated dust The movement passage P becomes small so that the volume can be reduced in the process of moving the separated dust downward.

That is, the space formed by the compression ribs 162 and the inner peripheral surface of the compression unit 113 becomes smaller toward the lower side of the compression unit 113, so that the compression ribs 162 and the compression unit 113 Dust is compressed by the inner circumferential surface.

As such, according to the present exemplary embodiment, since the dust separated by the dust separator 112 is stored in the dust storage unit 114 in a state where the volume is reduced while passing through the compression unit 113, the dust storage unit The dust collecting capacity of 114 can be increased.

In addition, the rotation member 161 is seated on the upper side of the discharge pipe 150 is in communication with the discharge pipe 150. In addition, a through hole 166 through which air may pass is formed on an upper surface of the rotating member 161.

When the upper cover 120 to which the filter member 140 is coupled is coupled to the dust separation unit 112, the filter member 140 is seated on the upper side of the rotating member 161. When the filter member 140 is seated on the upper side of the rotating member 161, the rotation shaft 164 of the rotating member 161 penetrates up and down the inside of the filter member 140.

Therefore, since the filter member 140, the rotating member 161, and the discharge pipe 150 communicate with each other, air introduced into the filter member 140 passes through the rotating member 161 and the discharge pipe 150. It is discharged to the outside of the dust collecting body 110 through the discharge hole (152).

Here, the filter member 140 is seated on the upper side of the rotating member 161 in the state in which the rotating member 161 is seated on the discharge pipe 150, the upper and lower sides of the rotating member 161 is supported. do. Therefore, the up and down swing can be prevented during the rotation of the rotating member 161, the rotation member 161 can be smoothly rotated.

The compression member 160 is rotated by the driving device. Therefore, hereinafter, the driving device will be described.

The driving device may include a compression motor 210 provided to the dust collector mounting unit 16, a drive gear 220 coupled to the compression motor 210, and the compression motor 210 from the drive gear 220. A driven gear 230 that receives the driving force of) is included.

In detail, the driven gear 230 is coupled to an upper side of the upper cover 120. The gear shaft 232 of the driven gear 230 penetrates the upper cover 120, and the rotation shaft 164 of the rotation member 161 is coupled to the gear shaft 232.

As the driven gear 230 is coupled to the upper cover 120, the driven gear 230 is exposed to the outside of the dust collecting device 100.

In addition, the driving gear 220 is exposed to the dust collector mounting part 16 in a state coupled to the compression motor 210. To this end, the dust collector mounting part 16 is formed with an opening 20 for exposing a part of the outer circumferential surface of the drive gear 220 to the dust collector mounting part 16.

As the driven gear 230 is exposed to the outside of the dust collecting device 100 and the driving gear 220 is exposed to the dust collecting device mounting part 16, the dust collecting device mounting part 16 is collected. When the device 100 is mounted, the driven gear 230 is engaged with the drive gear 220.

Accordingly, when the compression motor 210 is rotated, the drive gear 220 coupled with the compression motor 210 is rotated, and the rotational force of the compression motor 210 is driven by the drive gear 220. The driven member 230 is transmitted to the gear 230 to rotate. Finally, the rotating member 161 is rotated by the rotation of the driven gear 230.

Hereinafter, the operation of the dust collector and the dust compression process will be described.

4 is a view showing an air flow and dust compression process in the dust collecting apparatus according to the first embodiment.

Referring to FIG. 4, in order to perform cleaning, the dust collecting device 100 is mounted on the dust collecting device mounting part 16. When the dust collector 100 is mounted on the dust collector mounting unit 16, the driven gear 230 is connected to the driving gear 220 exposed by the dust collector mounting unit 16. Therefore, the compression member 160 inside the dust collecting apparatus 100 is in a rotatable state.

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 14 is introduced into the cleaner body 10 through the body suction unit 17, and the introduced air is introduced into the dust collector 100 through a predetermined flow path. do.

In detail, the air containing the dust is sucked in the tangential direction of the dust separation unit 112 through the inlet 111 of the dust separation unit 112. Then, the sucked air falls while turning along the inner circumferential surface of the dust separation unit 112, in this process, the air and dust are separated from each other while receiving different centrifugal force by the weight difference.

In addition, the dust is separated air is introduced into the filter member 140 through the through-hole 142 of the filter member 140, the introduced air is inside the rotating member 161 and the discharge pipe 150 Is moved downward while passing through the discharge hole 152 is discharged to the outside.

On the other hand, the separated dust falls to the upper side of the compression rib 162 of the compression member 160 in the course of turning along the inner peripheral surface of the dust separation unit 112.

As the suction motor is operated and the dust separation process is performed, the compression member 160 is rotated by the compression motor 210 so that the separated dust is moved to the dust storage unit 114. Compression is performed.

In detail, after the suction motor is operated or at the same time as the suction motor is operated, power is applied from the cleaner body 10 to the compression motor 210 to rotate the compression motor 210. When the compression motor 210 is rotated, the drive gear 220 is rotated, and the compression member 160 is rotated in one direction by the rotation of the drive gear 220.

In addition, when the compression member 160 is rotated, the dust dropped on the compression rib 162 is helically moved downward by the compression rib 162, and as described above, the dust is moved downward. Dust is compressed by the compression rib 162 and the inner circumferential surface of the compression unit 113. Then, the dust compressed while moving downward is dropped into the dust storage unit 114 and stored.

In addition, the compression motor 210 is stopped while the operation of the suction motor is stopped.

Then, the lower cover 130 is opened to discharge the dust stored in the dust storage unit 114. Then, the dust stored in the dust storage unit 114 is discharged in a lumped state.

Therefore, according to the present embodiment, since the separated dust is compressed in the process of moving to the dust storage unit 114, 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 storage unit 114, the scattering of dust may be prevented in the process of emptying the dust.

5 is a vertical cross-sectional view of the dust collecting apparatus according to the second embodiment, and FIG. 6 is a cross-sectional view showing an upper structure of the dust collecting unit mounting portion according to the second embodiment.

5 and 6, the dust collecting apparatus 300 according to the present embodiment includes a dust collecting body 310 forming an external shape, an upper cover 320 coupled to an upper side of the dust collecting body 310, and A lower cover 330 coupled to the lower side of the dust collecting body 310 to discharge dust to the outside, a compression member 360 provided inside the dust collecting body 310 to compress the dust, and the upper cover A driving device 400 provided at 310 to drive the compression member 360 is included.

In the present embodiment, since the configuration of the dust collecting body is the same as the original embodiment, detailed description thereof will be omitted.

In detail, the driving device 400 is detachably coupled to an upper side of the upper cover 320. In addition, the driving device 400 is a motor coupled to the compression motor 420 for rotating the compression member 360 and the upper cover 320 and allowing the compression motor 420 to be received therein. Housing 410 is included.

The motor housing 410 is coupled to the fastening rib 322 formed above the upper cover 320 in a state where the compression motor 410 is accommodated therein.

A fastening protrusion 412 is formed at an outer side of the motor housing 410, and a protrusion insertion hole 323 is formed at the fastening rib 322 to selectively insert the fastening protrusion 412.

In addition, a shaft coupling portion 365 formed on an upper side of the rotation shaft 364 of the compression member 360 and penetrating the upper cover 320 is coupled to the motor shaft 422 of the compression motor 420. .

Accordingly, when the compression motor 420 is rotated, the rotation shaft 364 of the compression member 360 coupled with the compression motor 420 is rotated, and the compression member 360 is rotated by the rotation shaft 364. ) Is rotated.

In addition, a terminal portion 414 connected to the compression motor 420 is formed at a side of the motor housing 410. When the dust collector 300 is mounted on the dust collector mounting unit 500, the terminal unit 424 is connected to a power supply terminal 514 formed on the dust collector mounting unit 500 to supply power from the cleaner body 500. Supplied.

According to the present embodiment as described above, since the rotation shaft 364 of the compression member 360 is directly connected to the motor shaft 422 of the compression motor 420, there is an advantage that the power transmission can be made smoothly.

In addition, since the driving device 400 is detachably coupled to the dust collecting device 300, the driving device 400 may be separated from the dust collecting device 300 when the dust collecting device 300 is cleaned. Water may be prevented from entering the driving device 400.

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

Referring to FIG. 7, the dust collecting apparatus 600 according to the present embodiment includes a dust collecting body 610 forming an external shape, an upper cover 620 coupled to an upper side of the dust collecting body 610, and the dust collecting body ( A lower cover 630 coupled to the lower side of the 610 to allow dust to be discharged to the outside; a compression member 660 provided inside the dust collecting body 610 to compress the dust; and the upper cover 610. Included is a drive device 700 provided to drive the compression member 660.

In detail, the driving device 700 is detachably coupled to the upper cover 620. The driving device 700 includes a compression motor 720 for rotating the compression member 660, a motor housing 710 in which the compression motor 720 is accommodated, and the compression motor 720. A power supply unit 730 for supplying power is included.

In the motor housing 720, a partition 712 is formed to partition a space in which the compression motor 720 is accommodated and a space in which the power supply 730 is accommodated.

In addition, the compression motor 720 is accommodated below the compartment 712, and the power supply unit 730 is accommodated above the compartment 712.

In addition, the partition part 712 is provided with a terminal part 714 connected to the compression motor 710. The terminal unit 714 is connected to the power supply unit 730 when the power supply unit 730 is accommodated in the motor housing 710.

Therefore, the compression motor 720 receives power from the power supply unit 730 accommodated in the motor housing 710. In this case, the power supply unit 730 may be a battery, for example.

In addition, a cover 713 for replacing the power supply unit 730 is provided on the upper side of the motor housing 710. The cover 713 may be rotatably coupled to the motor housing 710 or detachably coupled to the motor housing 710.

According to the present embodiment as described above, since the terminal unit 714 connecting the compression motor 710 and the power supply unit 730 is not exposed to the outside, the aesthetics are improved, and the user is safe.

8 is a block diagram showing a control structure of the driving apparatus according to the third embodiment.

Referring to FIG. 8, the control structure of the driving apparatus according to the present embodiment includes a transmission unit 750 for transmitting an operation manipulation signal of the compression motor 720, and the compression motor 720 from the transmission unit 750. A receiving unit 740 for receiving an operation signal and a control unit 730 for operating the compression motor 720 according to the signal received by the receiving unit 740.

In detail, the transmitter 740 is a part for transmitting an operation signal for turning on / off the compression motor 720, and a handle 11 (refer to FIG. 1) connected to an extension pipe or a handle of the dust collecting device 600. Can be formed on.

In addition, the receiver 740 and the controller 730 are provided inside the driving device 700.

Therefore, the compression motor 720 can be controlled by the operation of the user separately from the operation of the suction motor.

According to the embodiment as proposed, since the separated dust is compressed by the compression member and stored in the dust storage unit, 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 dust, 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 that the scattering of dust in the process of emptying the dust is prevented.

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 (9)

Dust separator; A dust storage unit storing dust separated from the dust separation unit; A compression unit connecting the dust separation unit and the dust storage unit; A compression member provided to the compression unit to guide the separated dust to be moved to the dust storage unit, and compressing the dust during the movement of the dust; And And a drive device for driving the compression member. The method of claim 1, The compression member is a rotating member rotated by the drive device, A rotating shaft connected to the driving device; Vacuum cleaner including a compression rib formed spirally on the outside of the rotating member. The method of claim 2, The compression rib is a vacuum cleaner that becomes smaller in width from the dust separation unit side toward the dust storage unit side. The method of claim 1, The driving device is a vacuum cleaner coupled to the dust separator. The method of claim 1, The drive device includes a compression motor provided in the cleaner body, A drive gear coupled with the compression motor, Includes a driven gear coupled to the dust separation unit, And the driving gear and the driven gear are engaged as the dust separator is mounted on the cleaner body. The method of claim 1, The dust separation unit is provided with a filter member for filtering the air, The dust storage unit is formed with a discharge hole for discharging the air through the dust separation process, the discharge pipe for guiding the air to the discharge hole, And the compression member communicates with the discharge pipe and the filter member. The method of claim 6, The rotary shaft of the compression member passes through the filter member. A dust collecting body having a compressing portion whose diameter decreases from an upper side to a lower side; A compression member provided in the compression unit; A compression rib formed in a spiral shape on an outer side of the compression member; And A driving device for rotating the compression member is included, And the dust separated from the dust collecting body passes through the compression unit, and the dust is compressed by the inner circumferential surface of the compression unit and the compression rib while the separated dust passes through the compression unit. The method of claim 8, The compression ribs are formed in the vacuum cleaner so that the width becomes smaller toward the direction in which the dust moves.

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