KR20110128469A - A vacuum cleaner - Google Patents

Abstract

PURPOSE: A vacuum cleaner is provided to prevent dust and foreign materials from scattering inside a dust compression unit by conglomerating the dust and foreign materials using a liquid material having viscosity. CONSTITUTION: A vacuum cleaner comprises a main body, a vacuum motor, a dust separation unit, a dust collection unit, and a dust compression unit(300). The dust separation unit is connected to the vacuum motor and separates dust from the main body. The dust collection unit collects dust separated from the dust separation unit. The dust compression unit is arranged between the dust separation unit and the dust collection unit and is selectively connected to the vacuum motor or external air. The dust compression unit compresses the dust separated from the dust separation unit.

Description

Vacuum cleaner {A VACUUM CLEANER}

The present invention relates to a vacuum cleaner, and more particularly, to a vacuum cleaner that can increase user convenience by compressing dust sucked into the vacuum cleaner.

In general, a vacuum cleaner is a device that sucks dust and foreign substances together with air by using a vacuum motor mounted inside the main body and then filters the same inside the main body.

The vacuum cleaner having the above function can be classified into a canister method in which a suction nozzle, which is a suction port, is communicated through a connection pipe with a main body, and an up-right method in which the suction nozzle is integrally formed with the main body. .

Among the two types of vacuum cleaners, the canister type vacuum cleaner includes a cleaner main body including a vacuum motor for generating suction power, a suction nozzle for sucking dust and foreign substances on the surface to be cleaned by the suction power generated by the cleaner main body, and the main body. And an extension pipe and a connection pipe for connecting the suction nozzle and the like.

That is, when power is applied to the main body of the vacuum cleaner and the vacuum motor is driven, suction force is generated, and air containing dust and foreign matter on the surface to be cleaned is sucked by the suction nozzle.

And air containing dust and foreign matter is introduced into the vacuum cleaner body through the extension pipe and the connection pipe. Air including dust and foreign matter introduced into the vacuum cleaner body is separated from dust and foreign matter by the cyclone principle in the dust separator mounted on the vacuum cleaner body.

The dust and foreign matters separated as described above remain in the dust separation unit of the vacuum cleaner, or when the dust collection unit communicating with the dust separation unit is provided separately, it is stored in the dust collection unit. And the air from which dust and foreign matters are discharged to the outside of the cleaner body through a filter.

On the other hand, when the dust and foreign matters separated from the dust separation unit accumulates in the dust separation unit or the dust collector, the user can separate the dust separation unit or dust collection unit from the main body and discard the foreign matter therein.

However, the accumulated dust and foreign matters may be scattered in the dust separator or the dust collector by the light weight, and the dust or the dust collector may be scattered even when the foreign matter is separated from the main body and discarded.

The present invention is to solve the above-described problems, the dust compression unit that can be agglomerated to prevent them from scattering dust and foreign matters separated from the dust separation unit to form a lump having a certain size is provided separately from the dust separation unit The dust compression unit is for providing a vacuum cleaner operated by a vacuum motor.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

Vacuum cleaner of the present invention for achieving the above object, the main body; A vacuum motor provided in the main body; A dust separator provided to communicate with the vacuum motor and separating dust; A dust collector provided adjacent to the dust separator to collect dust separated from the dust separator; And a dust compressing unit disposed between the dust collecting unit and the dust separating unit and selectively communicating with the vacuum motor or the external atmosphere to compress the dust discharged from the dust separating unit. The dust compression unit may include a dust compression member configured to compress dust by driving by a pressure gradient between the inside of the dust compression unit and the vacuum motor or a pressure gradient between the inside of the dust compression unit and the external atmosphere. It is characterized in that the configuration.

In another embodiment, the vacuum cleaner of the present invention for achieving the above object, the main body; A vacuum motor provided in the main body; A dust separator provided to communicate with the vacuum motor and separating dust; A dust collector provided adjacent to the dust separator to collect dust separated from the dust separator; And a dust compressing unit disposed between the dust collecting unit and the dust separating unit and selectively communicating with the vacuum motor or the external atmosphere to compress the dust discharged from the dust separating unit. The dust compression unit may include: a dust compression member configured to compress dust by driving by a pressure gradient between the inside of the dust compression unit and the vacuum motor or a pressure gradient between the inside of the dust compression unit and the external atmosphere; An opening / closing member which is driven by a pressure gradient between a dust compression unit and the vacuum motor or a pressure gradient between the dust compression unit and the external atmosphere, and selectively opens and closes between the dust compression unit and the dust collecting unit, and the dust compression unit And a case accommodating the member and the opening / closing member and having a discharge port for discharging the compressed dust to the dust collecting part.

As another embodiment, the vacuum cleaner of the present invention for achieving the above object, the main body; A vacuum motor provided in the main body; A dust separator provided to communicate with the vacuum motor and separating dust; A dust collector provided adjacent to the dust separator to collect dust separated from the dust separator; And a dust compressing unit disposed between the dust collecting unit and the dust separating unit and selectively communicating with the vacuum motor and the external atmosphere to compress the dust discharged from the dust separating unit. A plurality of dust compression members driven by a pressure gradient between the dust compression unit and the vacuum motor or by a pressure gradient between the dust compression unit and the external atmosphere and performing mutual compression on dust disposed therein; Characterized in that comprises a.

According to the present invention, when dust and foreign substances, etc., present on the surface to be cleaned are introduced into the vacuum cleaner during the use of the vacuum cleaner, the user can be compressed by compressing the dust and foreign substances in the dust compression unit operated by a vacuum motor. Increase

In addition, the viscous liquid material is discharged from the liquid supply device and mixed with the dust and foreign substances to prevent scattering of dust and foreign substances in the dust compressing unit, and the user separates the dust collecting unit from the vacuum cleaner main body. In the case of cleaning, dust and foreign matters may be thrown out in the form of lumps without being scattered, thereby increasing user convenience.

In addition, the dust collecting unit is provided separately from the dust separating unit has the advantage that it is easy to separate only the dust collecting unit in the vacuum cleaner body.

1 is a perspective view of a vacuum cleaner according to an embodiment of the present invention.
2 is an exploded perspective view of a vacuum cleaner main body according to an embodiment of the present invention.
3 is a perspective view illustrating a combined state of a dust separator, a dust compressor, and a dust collector according to one embodiment of the present invention.
Figure 4 is a side cross-sectional view showing the operation of the vacuum cleaner according to an embodiment of the present invention.
5 is a plan view of a dust compaction unit according to an embodiment of the present invention.
6 to 8 are front views showing various forms of the first movement member according to an embodiment of the present invention.
9 is a plan view of a dust compaction unit according to another embodiment of the present invention.
10 is a side view showing a state in which the cover and the collecting container is separated according to an embodiment of the present invention.
11 is a front view illustrating a state in which the first movement member is contracted and the second movement member is extended according to an embodiment of the present invention.
FIG. 12 is a plan view illustrating a first flow path part and a second flow path part according to the state of FIG. 11.
13 to 14 are front views showing a state in which the first movement member and the second movement member according to an embodiment of the present invention are extended.
FIG. 15 is a plan view illustrating a first flow path part and a second flow path part according to the states of FIGS. 13 to 14.
16 to 17 are front views illustrating a state in which a first movement member is extended and a second movement member is contracted according to an embodiment of the present invention.
FIG. 18 is a plan view illustrating a first channel part and a second channel part according to the states of FIGS. 16 to 17.
19 is a front view illustrating a state in which the first movement member is contracted and the second movement member is extended according to an embodiment of the present invention.
20 is a plan view illustrating a first channel portion and a second channel portion in accordance with the state of FIG. 19.
21 is a front view illustrating a combined state of the dust separator, the dust compressor, and the dust collector according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the contents throughout the specification.

In addition, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention may easily implement other embodiments within the scope of the same idea, but this also falls within the scope of the present invention. Of course.

1 is a perspective view of a vacuum cleaner according to an embodiment of the present invention. Referring to Figure 1 will be described in detail the configuration and operation of the vacuum cleaner of the present invention.

The vacuum cleaner shown in FIG. 1 includes a main body 10 generating suction power using the vacuum motor 100, a connection part 20 for transmitting the suction power generated in the main body 10, and a connection part 20 on one side. It is configured to include a suction nozzle 30 which is provided to suck the dust and foreign matter and the like scattered on the surface to be cleaned together with the air.

The vacuum motor 100 is mounted inside the main body 10, and when the vacuum motor 100 is driven, suction force is generated to inhale dust and foreign matter together with the air into the main body 10. The sucked dust and foreign matter is filtered inside the main body 10.

The connection part 20 may be configured with an extension tube 22 having a suction nozzle 30 mounted at one end thereof and having an adjustable length, and a connection tube 24 connecting the extension tube 22 and the main body 10. Extension tube 22 can be used to adjust the length according to the height of the user of the vacuum cleaner or the position of the surface to be cleaned.

At the time of cleaning, the suction nozzle 30 connected to the extension pipe 22 moves back and forth and left and right with respect to the surface to be cleaned, so that the connection pipe 24 is formed of a flexible material so that the user can easily clean it. desirable.

2 is an exploded perspective view of the vacuum cleaner body 10 according to an embodiment of the present invention. Inside the main body 10 is provided with a dust separation unit 200 for separating the dust by sucking the air sucked in dust. That is, the dust separation unit 200 is composed of a cyclone system.

On the other hand, the front of the vacuum cleaner body 10 is provided with a space that is partially accommodated in the collecting container 620 constituting the dust collecting unit 600, the collecting container 620 is detachably accommodated in the main body 10 do.

In addition, a dust compression unit 300 is disposed between the dust separation unit 200 and the dust collecting unit 600 to compress the dust separated from the dust separation unit 200. The dust compression unit 300 is the Although it has a cylindrical shape in communication with the dust separation unit 200, a square pillar or a polygonal pillar may be used, and the present invention is not limited by the shape.

3 is a perspective view illustrating a combined state of the dust separation unit 200, the dust compression unit 300, and the dust collecting unit 600 according to an embodiment of the present invention. Referring to Figure 3 will be described in detail the configuration and operation of the dust separation unit 200, dust compression unit 300 and dust collector 600 of the present invention.

The dust separation unit 200 has a cylindrical shape as a whole, and is mounted on the main body 10 of the vacuum cleaner as described above. In addition, a suction part 210 is formed at the lower side of the dust separator 200 to suck outside air mixed with dust into the main body 10.

On the other hand, the front of the dust separation unit 200 is provided with a communication unit 220 for discharging the dust separated from the air sucked through the suction unit 210 to the dust compression unit 300, dust separation unit 200 Both sides of the inside are provided with an air discharge member 240 including a plurality of through holes.

Therefore, the air sucked through the suction unit 210 is discharged to the outside of the main body 10 through the discharge unit 230 provided on both sides of the dust separation unit 200 after passing through the air discharge member 240. do. Here, the suction part 210, the communication part 220, and the discharge part 230 are provided to communicate with each other.

That is, the vacuum motor 100 provided in the main body 10 of the vacuum cleaner communicates with the discharge part 230 to form a vacuum pressure, and the suction part 210 sucks the outside air by the vacuum pressure. do.

In addition, the dust mixed in the air sucked through the suction unit 210 is discharged to the dust compression unit 300 through the communication unit 220 while flowing inside the dust separation unit 200, thereby separating the dust The unit 200 separates dust from the sucked air.

On the other hand, the upper side of the dust separation unit 200 is provided with a detachable knob 250 for separating the dust separation unit 200 from the main body 10. Therefore, when the user cleans or repairs the inside of the dust separation unit 200, the dust separation unit 200 may be easily separated from the main body 10.

On the other hand, the dust separated in the dust separation unit 200 is discharged to the dust compression unit 300 is compressed in the dust compression unit 300.

Here, the dust compressing unit 300 is disposed between the dust collecting unit 600 and the dust separating unit 200, provided to selectively communicate with the vacuum motor 100 or the atmosphere outside the main body 10 provided in the main body 10. And comprises a dust compressing member 310.

The dust compressing member 310 is driven by a pressure gradient between the dust compressing unit 300 and the vacuum motor 100 or by a pressure gradient between the dust compressing unit 300 and the outside atmosphere to compress the dust.

On the other hand, the vacuum cleaner of the present invention is provided in the first passage portion 410 and the first passage portion 410 for communicating the dust compression unit 300 with the vacuum motor 100 or the external atmosphere, the dust compression unit 300 It further comprises a first flow path switching unit 420 to selectively communicate with the vacuum motor 100 or the external atmosphere.

That is, the first flow path part 410 includes a first air flow path 412 and a first vacuum flow path 414, the first air flow path 412 is a dust compression unit 300 and the outside atmosphere. In communication, the first vacuum passage 414 communicates the dust compression unit 300 with the vacuum motor 100.

Therefore, when the first flow path switching unit 420 communicates the dust compression unit 300 with the external atmosphere, atmospheric pressure acts on the dust compression unit 300, and the first flow path switching unit 420 is When the dust compression unit 300 communicates with the vacuum motor 100, the vacuum pressure generated by the vacuum motor 100 acts on the dust compression unit 300.

Here, the operation process of the dust compression member 310 according to the atmospheric pressure or the vacuum pressure acts on the dust compression unit 300 will be described in detail below.

On the other hand, the vacuum cleaner of the present invention further includes an opening and closing member for selectively opening and closing between the dust compression unit 300 and the dust collector 600.

The opening and closing member is provided to selectively communicate with the vacuum motor 100 or the external atmosphere, and is driven by a pressure gradient between the dust compression unit 300 and the vacuum motor 100 or the external atmosphere to perform the opening and closing operation. .

On the other hand, according to another embodiment, the opening and closing member performs the opening and closing operation by operating by a drive motor provided separately.

Here, the configuration and operation process of the opening and closing member for selectively opening and closing between the dust compression unit 300 and the dust collecting unit 600 will be described in detail below.

On the other hand, the dust collector 600 is provided adjacent to the dust separator 200 to collect the dust separated from the dust separator 200. That is, the dust collecting unit 600 includes a cover 610 and a collecting container 620, the cover 610 is a communication for discharging the dust compressed by the dust compression unit 300 into the collecting container 620 Sphere 612 is formed.

Figure 4 is a side cross-sectional view showing the operation of the vacuum cleaner according to an embodiment of the present invention. As shown in FIG. 4, when the vacuum cleaner is operated, external air (shown in dotted lines) and dust and other foreign matter (shown in solid lines) are dusted through the suction unit 210 provided in front of the dust separator 200. It is introduced into the separation unit 200.

The dust and other foreign substances introduced into the dust separation unit 200 move along the inner circumferential surface of the dust separation unit 200 by centrifugal force, and are introduced into the dust compression unit 300 by the guide of the communication unit 220. .

Then, the air separated from the dust and other foreign matter by the dust separation unit 200 passes through the air discharge member 240 provided in the dust separation unit 200, after passing through the vacuum motor 100, the body 10 Discharged to the outside.

5 is a plan view of the dust compressing unit 300 according to an embodiment of the present invention. Referring to Figure 5 will be described in detail the configuration and operation of the dust compression unit 300 of the present invention.

The dust compressing unit 300 includes a dust compressing member 310, an opening and closing member, and a case 340 for accommodating the dust compressing member 310 and the opening and closing member, and the dust compressing member 310 includes a piston ( 312), compression plate 314 and first movement member 316.

The case 340 forms an appearance of the dust compressing unit 300 and communicates with the dust separating unit 200. That is, the case 340 has a cylindrical shape extending in the left and right directions, and the inlet 342 through which the dust separated from the dust separator 200 flows is formed.

In addition, the piston 312 reciprocates along the longitudinal direction of the case 340 inside the case 340. Accordingly, the piston 312 preferably has an appearance corresponding to the internal shape of the case 340.

In addition, the piston 312 is preferably formed in an empty form to have a light weight to facilitate the reciprocating motion inside the case 340.

In addition, the compression plate 314 is disposed on one side of the piston 312 to compress the dust separated from the dust separation unit 200.

That is, as the piston 312 reciprocates, the compression plate 314 disposed on one side of the piston 312 also reciprocates along the length direction of the case 340, and is separated from the dust separation unit 200. The dust is compressed by the compression plate 314.

On the other hand, the compression plate 314 preferably has an appearance that corresponds to the internal shape of the case 340 in order to facilitate reciprocating movement inside the case 340 like the piston 312.

In addition, the compression plate 314 may be integrally formed with the piston 312, may be formed separately from the piston 312 may be coupled to one side of the piston 312.

On the other hand, the first movement member 316 is accommodated in the piston 312, the first movement member 316 is coupled to one surface of the compression plate 314 by stretching in the longitudinal direction of the case 340 The piston 312 is in reciprocating motion.

That is, as described above, the dust compression member 310 is driven by a pressure gradient between the dust compression unit 300 and the vacuum motor 100 or by a pressure gradient between the dust compression unit 300 and the external atmosphere. The first movement member 316 expands and contracts by a vacuum or atmospheric pressure applied to the inside of the first movement member 316 communicating with the first flow path part 410. As it expands and contracts, the compression plate 314 compresses dust.

Specifically, when the vacuum cleaner of the present invention operates, the dust compression unit 300 is formed with a pressure lower than atmospheric pressure by the vacuum pressure generated by the vacuum motor 100 provided in the main body 10.

On the other hand, when the first passage portion 410 is connected to the first air passage 412 and the atmospheric pressure acts on the inside of the first movement member 316, the dust compression portion inside the first movement member 316 A pressure higher than the interior of 300 is formed. Therefore, the first movement member 316 extends along the longitudinal direction of the first case 340.

In addition, when the first flow path part 410 is connected to the first vacuum flow path 414 and a vacuum pressure is applied to the inside of the first moving member 316, dust is compressed inside the first moving member 316. A pressure lower than the inside of the part 300 is formed. Accordingly, the first movement member 316 contracts along the length direction of the case 340.

Even when a vacuum pressure is applied to both the inside of the first movement member 316 and the inside of the dust compression unit 300, the first movement member 316 is directly connected to the vacuum motor 100 through the first flow path 410. This is because the pressure loss occurs because the vacuum pressure of the vacuum motor 100 is applied to the inside of the dust compression unit 300 after passing through the dust separation unit 200.

That is, due to the pressure gradient generated according to the pressure difference in the vacuum pressure or the external atmosphere of the vacuum motor 100 applied to the inside of the first movement member 316 as described above, and the pressure inside the dust compression unit 300. The first movement member 316 is stretched, and the dust is compressed by the expansion and contraction of the first movement member 316.

In addition, since the dust compressing member 310 is operated by the vacuum pressure generated by the vacuum motor 100, the piston 312 may move the inside of the case 340 to compress the dust introduced from the dust separating part 200. The reciprocating motion has an advantage of preventing noise.

On the other hand, the peripheral surface of the compression plate 314 is preferably formed to be spaced apart from the inner surface of the case 340 by a predetermined distance. Referring to FIG. 5, the diameter of the disk-shaped compression plate 314 is smaller than the diameter inside the case 340.

If the circumferential surface of the compression plate 314 is formed to be in contact with the inner surface of the case 340, the piston 312 facilitates the reciprocating motion due to the friction between the compression plate 314 and the inner surface of the case 340. This is because dust may be easily caught on one surface of the compression plate 314 to which the movement member is coupled.

On the other hand, if the circumferential surface of the compression plate 314 and the inner surface of the case 340 are separated by a predetermined distance or more, some dust existing between the circumferential surface of the compression plate 314 and the inner surface of the case 340 is compressed. A problem arises that it is difficult to be.

Therefore, the predetermined distance between the circumferential surface of the compression plate 314 and the inner surface of the case 340 is preferably 3mm to 7mm.

On the other hand, the dust compressing unit 300 is disposed on the outer surface of the case 340, and communicates with the inside of the case 340 is further provided with a liquid supply device 360 for supplying a liquid material to the inside of the case 340 It is configured to include.

That is, the dust separated from the dust separation unit 200 is introduced into the case 340 through the inlet 342, the dust or other foreign matter introduced into the case 340 can be easily scattered The liquid supply device 360 is provided in order to prevent it from being.

The liquid substance is preferably composed of a liquid having a certain viscosity. This is to form a lump having a predetermined weight by attaching dust and other foreign matters to each other easily by the viscosity of the liquid substance.

According to one embodiment, the liquid supply device 360 is preferably provided to be located on one side of the Sangik inlet 342. That is, the dust separated by the dust separation unit 200 is introduced into the case 340 through the inlet 342, and the liquid material is directly supplied to the dust introduced through the inlet 342 to scatter dust. This is to prevent it.

On the other hand, the dust compression unit 300 includes an opening and closing member for selectively opening and closing between the dust compression unit 300 and the dust collecting unit 600, the opening and closing member also similar to the dust compression member 310, the vacuum motor 100 Or is provided to be selectively communicated with an external atmosphere, and is driven by a pressure gradient between the inside of the switching device and the vacuum motor 100 or the external atmosphere to perform the opening and closing operation.

On the other hand, the opening and closing member 320 includes a separation plate 322, the second movement member 324, the separation plate 322 by opening and closing the discharge port 344 formed in the case 340, the dust compression unit 300 And selectively open and close between the dust collector 600.

That is, when the separating plate 322 closes the discharge port 344, the separating plate 322 compresses dust together with the compressing plate 314. In addition, when the separator 322 opens the discharge port 344, the compressed plate 314 pushes the compressed dust toward the discharge port 344, and the compressed dust covers the dust storage unit 610. Through the communication port 612 formed in the flow into the collection 620.

In addition, one end of the second movement member 324 is connected to the separator 322 to move the separator 322 to open and close the discharge port 344.

On the other hand, since the separator 322 opens and closes the discharge port 344 by reciprocating in the case 340, the separator 322 is formed of a disc corresponding to the shape of the inner surface of the case 340.

In addition, the second movement member 324 is accommodated in the case 340 and stretches in the longitudinal direction of the case 340. That is, any member may be used as long as the second movement member 324 is connected to the separator 322 to extend and contract in the longitudinal direction of the case 340.

On the other hand, as described above, the opening and closing member 320 is provided to selectively communicate with the vacuum motor 100 or the external atmosphere, the pressure gradient between the interior of the dust compression unit 300 and the vacuum motor 100 or the external atmosphere. It is driven by the opening and closing operation, a vacuum pressure or atmospheric pressure is applied to the interior of the second movement member 324 in communication with the second flow path 510, the second movement member 324 is stretched, As the two moving members 324 expand and contract, the separating plate 322 performs an opening and closing operation.

In detail, the operation process of the second movement member 324 is similar to the operation process of the first movement member 316, when the vacuum cleaner of the present invention operates, the vacuum motor 100 provided in the main body 10. Due to the vacuum pressure generated by the inside of the dust compression unit 300, a pressure lower than the atmospheric pressure is formed.

On the other hand, when the second flow path 510 is connected to the second air passage 512 and the atmospheric pressure acts on the inside of the second movement member 324, the dust compression portion inside the second movement member 324. A pressure higher than the interior of 300 is formed. Accordingly, the second movement member 324 extends along the length direction of the second case 340.

In addition, when the second flow path part 510 is connected to the second vacuum flow path 514 and a vacuum pressure acts on the inside of the second motion member 324, a dust collecting part is formed inside the second motion member 324. Pressure lower than the interior of 600) is formed. Accordingly, the second movement member 324 contracts along the length direction of the case 340.

Even when a vacuum pressure is applied to both the inside of the second movement member 324 and the inside of the dust compressing portion 300, the second movement member 324 directly passes the vacuum motor 100 through the second flow path portion 510. This is because the pressure loss occurs because the vacuum pressure of the vacuum motor 100 is applied to the inside of the dust collecting part 600 after passing through the dust separating part 200.

That is, the second pressure is generated by the pressure gradient generated according to the pressure difference in the vacuum pressure or the external atmosphere of the vacuum motor 100 applied to the inside of the second movement member 324 as described above, and the dust collector 600. The movement member 324 is stretched, and the separation plate 322 opens and closes the discharge port 344 formed in the case 340 by the expansion and contraction of the second movement member 324, thereby compressing the dust compressing portion 300 and the dust collecting portion ( 600 selectively opens and closes.

In addition, the opening and closing member is operated by the vacuum pressure generated by the vacuum motor 100, similar to the dust compression unit 300, so that when the opening and closing the discharge port 344 to discharge the compressed dust to the dust collecting unit 600, noise is It has the advantage of preventing it from happening.

6 to 8 are front views showing various forms of the first movement member 316 according to an embodiment of the present invention.

As described above, the first movement member 316 accommodated in the piston 312 is coupled to one surface of the compression plate 314 to expand and contract in the longitudinal direction of the case 340. The first movement member 316 may be any member as long as it is a member that extends and contracts in the longitudinal direction of the case 340.

6 is a perspective view illustrating the dust compressing member 310, wherein the first movement member 316 is a bellows 316a. That is, the bellows 316a communicates with the vacuum motor 100 or the external atmosphere by the first flow path part 410, and when the vacuum pressure is applied to the bellows 316a, the bellows 316a contracts in the longitudinal direction. When atmospheric pressure acts on the bellows 316a, it extends in the longitudinal direction.

By the contraction or extension of the bellows 316a, the piston 312 reciprocates in the case 340, and the compression plate 314 disposed on one side of the piston 312 compresses dust. .

And, Figure 7 is a perspective view showing a dust compression member 310, characterized in that the first movement member 316 is a telescopic cylinder (316b). That is, like the bellows 316a, the telescopic cylinder 316b also contracts or expands under the action of vacuum or atmospheric pressure.

In addition, similar to the bellows 316a, the piston 312 reciprocates in the case 340 by contraction or extension of the telescopic cylinder 316b, and a compression plate disposed at one side of the piston 312. 314 compresses the dust.

8 is a perspective view illustrating the dust compressing member 310, wherein the first movement member 316 is an air bag 316c. Like the bellows 316a and the telescopic cylinder 316b, the airbag 316c also contracts or expands under the action of vacuum or atmospheric pressure, whereby the piston 312 reciprocates inside the case 340. You exercise.

Meanwhile, the second movement member 324 of the opening and closing member 320 may also be provided as one of the bellows 324a, the telescopic cylinder 324b, or the airbag 324c, similarly to the dust compression member 310.

When the second movement member 324 is provided with the bellows 324a, the telescopic cylinder 324b, or the airbag 324c, each operation is the same as the operation of the dust compression member 310 described above. Therefore, description thereof will be omitted.

9 is a plan view of the dust compression unit 300 according to another embodiment of the present invention, the other side of the inside of the dust compression unit 300 opening and closing member for selectively opening and closing the dust compression unit 300 and the dust collector 600 330 is located.

On the other hand, the opening and closing member 330 shown in FIG. 9 is operated by a mechanical structure unlike shown in FIG. That is, the opening and closing member 330 is configured to further include a drive motor 336, the drive motor 336 transfers power to the third movement member 334, the third movement member received the power 334 moves the separator 332 to open and close the discharge port 344 formed in the case 340.

On the other hand, the case 340 is formed in communication with the inside of the case 340, the avoiding portion 346 for receiving the separation plate 332 is formed.

Therefore, when the separating plate 332 opens the discharge port 344, the third movement member 334 moves the separating plate 332 to the avoiding part 346 by the power transmitted from the driving motor 336. Move it. On the other hand, when the separation plate 332 closes the discharge port 344, the third movement member 334 moves the separation plate 332 from the avoiding part 346 by the power transmitted from the driving motor 336. It moves to the inside of the case 340.

According to one embodiment, when the separator 332 opens the discharge port 344, the third movement member 334 rotates toward the avoiding portion 346 around the rotation axis of the drive motor 336. When the third movement member 334 rotates, the separation plate 332 coupled to the third movement member 334 also rotates into the avoidance part 346, so that the separation plate 332 of the case 340 is rotated. It can move to the avoiding part 346 from inside.

When the separator 332 closes the discharge port 344, the third movement member 334 rotates toward the inside of the case 340 as opposed to when the discharge port 344 is opened. Therefore, the separating plate 332 coupled to the third movement member 334 also rotates toward the inside of the case 340, thereby moving the separating plate 332 from the avoiding part 346 to the inside of the case 340. Can be.

On the other hand, the avoiding part 346 is a place for receiving the separation plate 332, the inside of the avoiding part 346 is preferably formed larger than the thickness and diameter of the separation plate 332 having a disc shape. .

On the other hand, the dust compression unit 300 is a space portion 350 to prevent contact with the compressed dust and the case 340 when the dust compressed in the case 340 to the dust collector 600; It is configured to further include.

That is, a rectangular parallelepiped space 350 is formed around the discharge port 344 formed on the lower surface of the case 340. The horizontal length of the space 350 is equal to the horizontal length of the discharge port 344. It is formed larger than its size.

Therefore, the width of the space 350 is larger than the width of the discharge port 344, so that the dust compressed in the case 340 is easily discharged without contacting the inner surface of the case 340.

Although the space 350 has a rectangular parallelepiped shape surrounding the discharge hole 344 formed on the lower surface of the case 340 as shown in FIG. 3, the cylindrical part and the polygonal column may also have the horizontal and vertical shape of the discharge hole 344. It may be formed larger than the length is larger than the width of the discharge port 344, and the present invention is not limited by the shape.

On the other hand, when the second movement member 324 is operated by the vacuum motor 100 as described above, inside the case 340 there is a locking step 348 for limiting the moving distance of the separation plate 322 Is formed.

That is, when the second movement member 324 extends along the longitudinal direction of the case 340 and the separation plate 322 closes the discharge port 344, the separation plate 322 and the compression plate 314. When the dust is compressed, the separation plate 322 is located beyond the moving distance that can close the discharge port 344, the compressed dust can not be easily moved to the discharge port (344).

Therefore, it is preferable to form the locking step 348 on one side of the discharge port 344 to limit the moving distance of the separating plate 322 so that the compressed dust is accumulated on one side of the discharge port 344.

In this case, when the second movement member 324 is contracted so that the separator plate 322 opens the discharge hole 344, the dust accumulated on one side of the discharge hole 344 is reciprocated by the compression plate 314. Thereby easily moves in the direction of the discharge port 344.

10 is a side view showing a state in which the cover 610 and the collecting container 620 according to an embodiment of the present invention are separated.

As described above, a dust collecting unit 600 is disposed below the dust compressing unit 300 to collect the compressed dust. The dust collecting unit 600 includes a cover 610 and a collecting container 620.

Since the cover 610 and the collecting container 620 are provided in a detachable structure, the user may separate only the collecting container 620 from the cover 610 and discard the compressed dust.

11 to 20 are side views schematically illustrating a process of operating the dust compression member 310 and the opening and closing member according to an embodiment of the present invention, and a first flow path according to the states of the dust compression member 310 and the opening and closing member. A plan view of the part 410 and the second flow path part 510 is shown.

11 to 20, the first flow path unit according to the operation of the dust compression member 310 and the opening and closing device of the dust compression unit 300 and the state of the dust compression member 310 and the opening and closing device according to the present invention. An operation process of the 410 and the second channel 510 will be described in detail.

11 is a front view illustrating a state in which the first movement member 316 is contracted and the second movement member 324 is extended according to an embodiment of the present invention, and FIG. 12 is a first flow path according to the state of FIG. 11. A plan view of the part 410 and the second flow path part 510 is shown.

As shown in FIG. 11, the first movement member 316 of the dust compressing member 310 is in a contracted state inside the case 340, and the second movement member 324 of the opening / closing member is the case 340. It is in an extended state inside of.

Meanwhile, the first channel switching unit 420 includes a first valve 422 which is switched to selectively communicate the dust compressing member 310 with the first air passage 412 or the first vacuum passage 414. The second flow path switching unit 520 includes a second valve 522 which is switched to selectively communicate the opening / closing member with the second air flow path 512 or the second vacuum flow path 514.

That is, referring to FIG. 12, the first valve 422 is switched such that the first flow path part 410 communicates with the first vacuum flow path 414, and the second valve 522 is the second flow path part 510. Is switched to communicate with the second air passage 512.

Accordingly, the vacuum pressure generated by the vacuum motor 100 acts on the first movement member 316, and a pressure lower than the pressure inside the dust compression unit 300 is formed inside the first movement member 316. . Therefore, the first movement member 316 is in a contracted state.

In addition, an external atmospheric pressure of the main body 10 acts on the second movement member 324, and a pressure higher than the pressure inside the dust compression unit 300 is formed inside the second movement member 324. Therefore, the second movement member 324 is in an extended state, and the separating plate 322 coupled with the second movement member 324 closes the discharge port 344 formed on the bottom surface of the case 340.

13 to 14 are front views showing a state in which the first movement member 316 and the second movement member 324 are extended according to an embodiment of the present invention, and FIG. 15 is a view according to the states of FIGS. 13 to 14. FIG. 1 is a plan view illustrating the first channel part 410 and the second channel part 510.

As shown in FIGS. 13 to 14, the first movement member 316 of the dust compression member 310 extends inside the first case 340, and the second movement member 324 of the opening / closing member also includes a case ( 340 is in an extended state.

That is, referring to FIG. 15, the first valve 422 is switched such that the first flow path part 410 communicates with the first air flow path 412, and the second valve 522 is also the second flow path part 510. Is switched to communicate with the second air passage 512.

Accordingly, the external atmospheric pressure of the main body 10 acts on the first and second movement members 316 and 324, and compresses dust inside the first and second movement members 316 and 324. A pressure higher than the pressure inside the part 300 is formed.

Therefore, the first movement member 316 extends in the longitudinal direction of the case 340 to compress the dust separated from the dust separation unit 200, and the second movement member 324 is in the extended state as it is the separation plate ( 322 is in a state of closing the discharge port 344.

16 to 17 are front views illustrating a state in which the first movement member 316 is extended and the second movement member 324 is contracted according to an embodiment of the present invention, and FIG. 18 is a view of FIGS. 16 to 17. The first flow path part 410 and the second flow path part 510 according to the state is a plan view.

As shown in FIGS. 16 to 17, the first movement member 316 of the dust compression member 310 continues to extend inside the first case 340, and the second movement member 324 of the opening / closing member may be removed. It is contracted inside the two cases 340.

That is, referring to FIG. 18, the first valve 422 is switched such that the first flow path part 410 communicates with the first air flow path 412, and the second valve 522 is the second flow path part 510. Is switched to communicate with the second vacuum flow path 514.

Therefore, the external atmospheric pressure of the main body 10 continues to act on the first movement member 316, and a pressure higher than the pressure inside the dust compression unit 300 is formed inside the first movement member 316. Therefore, the first movement member 316 extends to compress the dust.

In addition, a vacuum pressure generated by the vacuum motor 100 is applied to the second movement member 324, and a pressure lower than a pressure inside the dust compression unit 300 is formed inside the second movement member 324. do. Therefore, the second movement member 324 is contracted, and the separating plate 322 coupled with the second movement member 324 opens the discharge port 344. Therefore, the dust compressed by the first movement member 316 is discharged to the dust collecting part 600 through the discharge port 344 formed in the case 340 and the communication port 612 formed in the cover 610.

19 is a front view illustrating a state in which the first movement member 316 is contracted and the second movement member 324 is extended, according to an embodiment of the present invention. FIG. 20 is a first flow path according to the state of FIG. 19. A plan view of the part 410 and the second flow path part 510 is shown.

That is, referring to FIG. 20, the first valve 422 is switched such that the first flow path part 410 communicates with the first vacuum flow path 414, and the second valve 522 is the second flow path part 510. Is switched to communicate with the second air passage 512.

Accordingly, the vacuum pressure generated by the vacuum motor 100 acts on the first movement member 316, and a pressure lower than the pressure inside the dust compression unit 300 is formed inside the first movement member 316. . Therefore, the first movement member 316 compresses the dust and then contracts again.

In addition, an external atmospheric pressure of the main body 10 acts on the second movement member 324, and a pressure higher than the pressure inside the dust compression unit 300 is formed inside the second movement member 324. Therefore, since the second movement member 324 is elongated again, the separator 322 coupled with the second movement member 324 closes the discharge hole 344 after the compressed dust is discharged to the dust collecting part 600.

On the other hand, the piston 312 of the dust compression member 310 reciprocates along the longitudinal direction inside the case 340, the separating plate 322 to open and close the discharge port 344 formed in the case 340 In this case, the period of the opening and closing operation of the separator 322 preferably has a period larger than the reciprocating motion of the piston 312.

That is, the reciprocating motion of the piston 312 is for compressing the dust flowing into the case 340, and the opening and closing operation of the separating plate 322 is the dust compressed by the repeated reciprocating motion of the piston 312 This is because it is for discharging to the inside of the dust collector 600.

According to one embodiment, the piston 312 is one reciprocating motion for 1 minute to 2 minutes, corresponding to the separation plate 322 is the piston 312 is 10 to 20 reciprocating motion If you can open and close once.

21 is a front view illustrating a combined state of the dust separation unit 200, the dust compression unit 300, and the dust collecting unit 600 according to another embodiment of the present invention. Referring to FIG. 21, the configuration and operation of the dust separation unit 200, the dust compression unit 300, and the dust collecting unit 600 according to another embodiment of the present invention will be described.

However, the same contents as those described above, such as the dust compression member 310 driven by the pressure gradient between the dust compression unit 300 and the vacuum motor 100 or the external atmosphere, will be omitted.

As shown in FIG. 21, the dust compressing unit 1300 according to another embodiment of the present invention accommodates the first dust compressing member 1310 and the second dust compressing member 1320 therein. That is, the first dust compressing member 1310 and the second dust compressing member 1320 are provided at both sides of the inside of the case 1330 constituting the dust compressing unit 1300, respectively.

The first dust compressing member 1310 and the second dust compressing member 1320 are disposed to face each other to compress the dust by mutual compression on the dust. Therefore, it does not have a separate opening / closing member.

On the other hand, the dust separated from the dust separator 1200 is introduced into the case 1330 through the inlet formed in the case 1330, the inlet is the first dust compression member 1310 and the second dust compression member 1320 is formed to face the point of contact with each other.

That is, the first dust compression member 1310 and the second dust compression member 1320 are for directly compressing the dust introduced into the case 1330 through the inlet.

In addition, a discharge port for discharging the dust compressed by the first dust compressing member 1310 and the second dust compressing member 1320 to the dust collecting unit 1100 may include the first dust compressing member 1310 and the second dust. The compression member 1320 is formed below the point of contact.

According to another embodiment of the present invention, since the opening and closing member for opening and closing the discharge port is not provided separately, the dust compressed by the interaction of the first dust compression member 1310 and the second dust compression member 1320 is This is to be stored in the dust collecting unit 1400 through the discharge port by the weight.

The cycles of the reciprocating motion of the first dust compressing member 1310 and the second dust compressing member 1320 respectively accommodated on one side and the other side of the case 1330 are the same. As described above, when the first dust compressing member 1310 and the second dust compressing member 1320 reciprocate at the same cycle, the point where the dust is compressed remains the same, so the compressed dust is discharged to the dust collector 1400 through the discharge port. Can be introduced.

On the other hand, the process of operating the dust compression member by the vacuum pressure or the external atmosphere generated by the vacuum motor 100, the first dust compression member and the second dust compression member 1320 is one of the bellows, telescopic cylinder or air bag Features to be formed and the like are as described above will be omitted.

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

10: main body 20: connecting portion
30: suction nozzle 100: vacuum motor
200: dust separation unit 300: dust compression unit
310: dust compression member 320: opening and closing member
340: case 1200: dust separator
1300: dust compression unit 1400: dust collecting unit
1500: euro part

Claims (24)

main body;
A vacuum motor provided in the main body;
A dust separator provided to communicate with the vacuum motor and separating dust;
A dust collector provided adjacent to the dust separator to collect dust separated from the dust separator; And
A dust compressing unit disposed between the dust collecting unit and the dust separating unit and selectively communicating with the vacuum motor or the external atmosphere to compress the dust discharged from the dust separating unit; Including,
The dust compressing unit includes a dust compressing member compressing dust, and an opening and closing member for selectively opening and closing between the dust compressing unit and the dust collecting unit,
And the dust compressing member and the opening / closing member are driven by a pressure gradient between the dust compressing unit and the vacuum motor or a pressure gradient between the dust compressing unit and the outside atmosphere. The method of claim 1,
The dust compression unit,
And a case accommodating the dust compressing member and the opening / closing member and having a discharge port configured to discharge the compressed dust to the dust collecting unit. The method of claim 2,
A first flow passage portion communicating the dust compression member with the vacuum motor or the external atmosphere; And
A first flow path switching unit provided in the first flow path to selectively communicate the dust compression member with the vacuum motor or the external atmosphere; Vacuum cleaner comprising a more. The method of claim 3,
The first euro part,
A first air passage for communicating the dust compression member with the external atmosphere,
And a first vacuum flow passage for communicating the dust compression member with the vacuum motor. The method of claim 4, wherein
The first flow path switching unit,
And a first valve switched to selectively communicate the dust compressive member with the first air passage or the first vacuum passage. The method of claim 3,
The dust compression member,
A piston reciprocating in the case,
A compression plate disposed on one side of the piston to compress the dust separated from the dust separation unit;
And a first movement member communicating with the first flow path part and accommodated in the piston to expand and contract in the longitudinal direction of the case. The method of claim 6,
The first moving member is a vacuum cleaner, characterized in that any one of a bellows, a telescopic cylinder or an air bag. The method of claim 6,
The peripheral surface of the compression plate and the inner surface of the case vacuum cleaner, characterized in that spaced apart by a predetermined distance. The method of claim 2,
A second flow path portion communicating the opening and closing member with the vacuum motor or the external atmosphere; And
A second flow path switching unit provided in the second flow path to selectively communicate the opening and closing member with the vacuum motor or the external atmosphere; Vacuum cleaner comprising a more. 10. The method of claim 9,
The second euro part,
A second air passage for communicating the opening / closing member with the external atmosphere;
And a second vacuum flow path for communicating the opening and closing device with the vacuum motor. The method of claim 10,
The second flow path switching unit,
And a second valve which is switched to selectively communicate the opening / closing member with the second air passage or the second vacuum passage. 10. The method of claim 9,
The opening and closing member,
A separating plate for opening and closing between the dust compressing unit and the dust collecting unit;
And a second movement member communicating with the second flow path part and connected to the separation plate to expand and contract in the longitudinal direction of the case. The method of claim 12,
The inside of the case is a vacuum cleaner, characterized in that the locking step is formed to limit the moving distance of the separation plate. The method of claim 12,
The second moving member is a vacuum cleaner, characterized in that any one of a bellows, a telescopic cylinder or an air bag. The method of claim 2,
The dust compression unit,
And discharging the compressed dust to the dust collecting part, wherein the vacuum cleaner further comprises a space part for preventing contact between the compressed dust and the case. The method of claim 2,
The dust compression unit,
And a liquid supply device disposed on an outer surface of the case and communicating with an inside of the case to supply a liquid material to the inside of the case. The method of claim 1,
The dust collecting unit,
A cover having a communication hole through which the dust compressed by the dust compression unit is introduced;
And a collecting container coupled to the cover and storing the compressed dust. The method of claim 17,
The collecting container is a vacuum cleaner, characterized in that detachable from the cover. main body;
A vacuum motor provided in the main body;
A dust separator provided to communicate with the vacuum motor and separating dust;
A dust collector provided adjacent to the dust separator to collect dust separated from the dust separator; And
A dust compression unit disposed between the dust collecting unit and the dust separating unit and selectively communicating with the vacuum motor and the external atmosphere to compress the dust discharged from the dust separating unit;
The dust compressing unit is driven by a pressure gradient between the inside of the dust compressing unit and the vacuum motor or a pressure gradient between the inside of the dust compressing unit and the outside atmosphere, and performs a mutual compression action on dust disposed therein. A vacuum cleaner comprising a plurality of dust compression members. 20. The method of claim 19,
A flow path portion communicating the dust compression portion with the vacuum motor or the external atmosphere; And
A flow path switching unit provided in the flow path unit and selectively communicating the dust compression unit with the vacuum motor or the external atmosphere; Vacuum cleaner comprising a more. The method of claim 20,
The dust compression member,
A first dust compressing member provided on one side of the dust compressing unit;
And a second dust compressing member provided on the other inner side of the dust compressing unit and disposed to face the first dust compressing member. The method of claim 21,
The flow path part includes a first flow path part provided in communication with one side of the dust compression part, and a second flow path part provided in communication with the other side of the dust compression part,
The first flow path switching unit may include a first flow path switching unit and a second flow path switching unit respectively provided in the first flow path unit and the second flow path unit to selectively communicate one side and the other side of the dust compression unit with the vacuum motor or the external atmosphere. Vacuum cleaner comprising a. The method of claim 22,
The dust compression unit further includes a case extending in the left and right directions to accommodate the first dust compression member and the second dust compression member to be movable.
The first dust compression member and the second dust compression member is a vacuum cleaner, characterized in that provided to be moved in the longitudinal direction of the case. The method of claim 22,
The first dust compression member is provided to be in communication with the first flow path portion so that its length can be elongated or contracted in accordance with the switching of the flow path of the first flow path switching portion,
The second dust compressing member is in communication with the second flow path portion, the vacuum cleaner, characterized in that the length of the second flow path switching unit is provided so that its length can be expanded or contracted.

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