KR20040050618A - Vacuum cleaner - Google Patents

Abstract

PURPOSE: A vacuum cleaner is provided to improve the efficiency of a vacuum cleaner by increasing suction force with a swirl and to prevent the flying of the dust by discharging the air entering a swirl generator toward the upper face. CONSTITUTION: A vacuum cleaner includes a dust suction part(110) for sucking dust. The dust suction part includes a nozzle(111) connected with a suction tube(30) and directly generating suction force and a swirl generator(115) generating a swirl in the air sucked into the nozzle. The swirl generator includes a cylindrical swirl guider(117) inserted to the center of a body, a swirl inlet(118) through which the wind discharged from a motor(23) flows into the swirl guider, and a motor discharge pipe(116) connecting the outlet of the motor with the swirl inlet.

Description

Vacuum Cleaner {VACUUM CLEANER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum cleaner, and more particularly, to a vacuum cleaner in which a vortex is generated in a dust suction unit to increase dust suction power.

In general, the vacuum cleaner sucks dust or foreign substances scattered on the floor by using a suction force generated by the driving of the motor built into the cleaner body through a brush, and the vacuum suction unit is connected to a dust suction unit connected through a flexible hose. Refers to a device that automatically cleans by inhaling dust and foreign matter into the dust collecting chamber.

1 is a block diagram showing the configuration of a vacuum cleaner. The vacuum cleaner is composed of a dust suction unit 10 for sucking dust and a suction pipe 30 for connecting the dust suction unit 10 and the main body 20. The main body 20 includes a motor 23 for generating a suction force, a dust collecting chamber 21 for filtering dust sucked by the suction pipe 30, and a filter 22.

The dust collecting chamber 21 filters out a large volume of sucked dust or foreign matter, and the filter 22 filters fine dust.

The operation state of the conventional vacuum cleaner configured as described above is as follows. First, when power is supplied to the main body 20 and the motor 23 is driven, suction force is generated in the cleaner so that the air outside the cleaner is sucked into the cleaner through the dust suction unit 10. That is, the suction force generated by the driving of the motor 23 built in the main body 20 sucks dust or foreign matter from the outside of the cleaner together with the air to the dust suction unit 10 and the main body 20 along the suction pipe 30. Will flow into.

As the dust or foreign matter introduced into the main body 20 passes through the dust collecting chamber 21, bulky and heavy foreign matter is accumulated, and fine dust is filtered while passing through the filter 22. Air passing through the filter 22 passes through the motor 23 to the outside of the main body 20 to be discharged to the atmosphere.

However, the conventional vacuum cleaner as described above simply sucks dust depending on the suction power of the motor, and thus the suction force is lowered compared to the capacity of the motor, so that the efficiency of the cleaner is reduced and energy consumption is large.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a vacuum cleaner to increase the suction power by generating a vortex in the dust suction unit using the air discharged from the motor.

1 is a block diagram showing the configuration of a vacuum cleaner

2 to 5 show the structure of the first embodiment of the present invention.

2 is a conceptual view of a vacuum cleaner

3 is a perspective view of a dust suction part of the vacuum cleaner of FIG.

4 is a perspective view of the nozzle of FIG.

Figure 5 is a bottom view of the nozzle of Figure 4

Fig. 6 shows the structure of a second embodiment of the present invention and is a perspective view of the dust suction unit.

Figure 7 is a graph comparing the suction distance of the first embodiment and the second embodiment

Fig. 8 shows the structure of a third embodiment of the present invention and is a perspective view of a dust suction unit.

9 and 10 show the structure of the fourth embodiment of the present invention.

9 is a perspective view of the dust suction unit;

10 is a longitudinal cross-sectional view of FIG.

11 and 12 show the structure of the fifth embodiment of the present invention.

11 is a longitudinal sectional view of the dust suction unit;

12 is a cross sectional view of FIG.

** Description of the symbols for the main parts of the drawings **

10: dust suction unit 23: motor

24: collecting device 30: suction pipe

111, 411, 511: nozzle 113: guide vane

115, 415, 515: Vortex Generator

117, 217, 417, 517: Vortex guide

118, 218, 418, 518: vortex generation inlet

219,319: Additional guide wall 450: Top discharge port

412: upper nozzle 413: lower nozzle

551: boundary ring 552: scattering ring

571: vortex guide discharge port

The present invention comprises a dust suction unit, a dust collector connected to the suction pipe from the dust suction unit to collect the suctioned dust to achieve the object as described above, and a motor for generating a suction force to the dust suction unit The vacuum cleaner of claim 1, wherein the dust suction part is connected to the suction pipe at one end to generate a direct suction input. It is connected to the motor discharge pipe connected to the discharge port of the motor, by using the air discharged from the motor to generate a vortex in the air sucked in the nozzle, and comprises a vortex generating device for discharging the air to the upper end It provides a vacuum cleaner.

Therefore, by using the air discharged from the motor to generate a vortex in the dust intake portion to increase the suction force, to increase the efficiency of the vacuum cleaner without using a separate power. In addition, by configuring the air introduced into the vortex generating device is discharged to the upper surface, it is possible to prevent the scattering of dust generated by the discharge to the lower surface.

In addition, the nozzle has a pipe shape, and the vortex generator is formed by inserting the nozzle in the center, and a vortex guider having a vortex guider inlet formed in accordance with the hollow of the nozzle on a lower surface thereof, and the wind discharged from the motor. A vortex generating inlet formed on the sidewall of the vortex guider so as to flow into the vortex guider, and having an inlet formed obliquely from the outside of the sidewall to allow wind to flow in the tangential direction of the vortex guider; It is preferable that the upper discharge port formed on the upper surface of the vortex guider is configured.

In addition, the nozzle is preferably configured to include a lower nozzle formed by fixing the lower end to the vortex guide inlet, the upper nozzle is axially spaced from the lower nozzle and one end connected to the suction pipe.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, in describing the present invention, a detailed description of known functions or configurations will be omitted in order not to disturb the gist of the present invention.

In addition, the same reference numerals are given to the same and the same components as those described above, and detailed description thereof will be omitted.

2 to 5 show the structure of the first embodiment of the present invention, FIG. 2 is a conceptual view of the vacuum cleaner, FIG. 3 is a perspective view of the dust suction unit of the vacuum cleaner of FIG. 2, and FIG. 4 is a view of the nozzle of FIG. 5 is a bottom view of the nozzle of FIG.

The vacuum cleaner is composed of a dust suction unit 110 for sucking dust and a suction pipe 30 for connecting the dust suction unit 110 and the main body 20. The main body 20 is composed of a motor 23 for generating a suction force, and a dust collector 24 for collecting dust sucked by the suction pipe 30. The dust collector 24 is composed of a dust collecting chamber 21 and a filter 22. The dust collecting chamber 21 filters out a large volume of sucked dust or foreign matter, and the filter 22 filters fine dust.

The dust suction unit 110 has a nozzle 111, one end of which is connected to the suction pipe 30 to generate a direct suction force, and a vortex generator 115 for generating a vortex in the air sucked into the nozzle 111. It is configured to include.

The vortex generator 115 generates the vortex by using the air discharged from the motor 23. In addition, the vortex generator 115 may enter the cylindrical vortex guider 117 and the wind discharged from the motor 23 to the inside of the vortex guide 117 so that the nozzle 111 is inserted into the center. And a motor discharge pipe 116 connecting the vortex generating inlet 118 and the outlet of the motor 23 and the vortex generating inlet 118 so as to be formed. The vortex generating inlet 118 is formed obliquely from the outside of the side wall of the vortex guider 117 into the wind flows through the vortex generating inlet 118 vortex along the inner surface of the vortex guider 117 To form.

The nozzle 111 is inclined inwardly inclined inward so that wind may flow in a tangential direction of the nozzle 111 to a part of the side 112 of the portion inserted into the vortex guide 11. ) Is formed. That is, as shown in Figure 5, the guide blade 113 is formed inclined inward the side 112 of the nozzle 111 so that air can flow in the direction of the arrow (114).

The operation of the first embodiment of the present invention will be described below.

When power is supplied to the main body 20 and the motor 23 is driven, suction force is generated in the cleaner so that the air outside the cleaner is sucked into the cleaner through the dust suction unit 110. That is, the suction force generated by the driving of the motor 23 embedded in the main body 20 sucks dust or foreign matter from the outside of the cleaner together with the air to the dust suction unit 110 and the main body 20 along the suction pipe 30. Will flow into.

As the dust or foreign matter introduced into the main body 20 passes through the dust collecting chamber 21, bulky and heavy foreign matter is accumulated, and fine dust is filtered while passing through the filter 22. The air passing through the filter 22 passes through the motor 23 and flows into the vortex generation inlet 118 through the motor discharge pipe 116.

Air introduced into the vortex guider 117 through the vortex generating inlet 118 flows along the inner surface of the vortex guider 117 to generate vortices. In addition, the air flows through the guide vane 113 of the nozzle 111 to generate a vortex in the suction flow 98 of the nozzle 111 to increase the suction force of the nozzle 111.

As described above, the present invention increases the suction force by generating a vortex in the dust suction unit 110 using the air discharged from the motor 23.

Fig. 6 shows the structure of a second embodiment of the present invention, and is a perspective view of the dust suction unit.

The second embodiment differs in the structure of the dust suction unit 210 from the first embodiment, and the other configurations are the same. Therefore, the configuration of the second embodiment will be described with reference to the dust suction unit 210.

The dust suction unit 210 includes a nozzle 111 for generating a suction force directly by using the suction force generated by the motor 23, and a vortex generator for generating a vortex in the air sucked by the nozzle 111. It is configured by.

The vortex generator generates vortices by using the air discharged from the motor 23. In addition, the vortex generator is formed such that the cylindrical vortex guider 217 and the wind discharged from the motor 23 can be introduced into the vortex guide 217 so that the nozzle 111 is inserted into the center. The vortex generation inlet 218 and the motor discharge pipe 116 which connects the discharge port of the motor 23 and the vortex generation inlet 218 are comprised. The vortex generation inlet 218 is formed obliquely from the outside of the side wall of the vortex guide 217 into the wind so that the wind flowing through the vortex generation inlet 218 is vortex along the inner surface of the vortex guider 117 To form.

In addition, the vortex generating device is formed in the air flowing in the vortex generating inlet 218 is formed extending from the lower portion of the vortex guider 217, the additional guide wall 219 extending the vortex of the air to form It is preferably configured to further include. That is, the air introduced through the vortex generation inlet 218 flows inside the vortex guider 217 as shown by the arrow 221, and the flow is discharged from the lower end of the vortex guider 217. By installing the additional guide wall 219, the vortex generated by the vortex guider 217 is formed to be extended to increase the suction distance.

7 is a graph comparing suction distances of the first embodiment and the second embodiment.

In the graph of Fig. 7, the horizontal axis represents the distance at the bottom of the vortex guiders 117 and 217, and the vertical axis represents the wind speed at the center.

As illustrated, when the same distance is separated from the vortex guiders 117 and 217, the wind speed is higher in the second embodiment 240 than in the first embodiment 140. That is, the second embodiment has a longer suction distance than the first embodiment.

8 shows the structure of a third embodiment of the present invention, and is a perspective view of the dust suction unit.

The structure of the third embodiment differs only in the shape of the second embodiment from the shape of the additional guide wall 319, and the other structures are the same.

As shown, the additional guide wall 319 is formed obliquely to the bottom, it may be in contact with the bottom surface obliquely. Therefore, the user can clean while tilting the dust suction unit 310 is easy to use.

9 and 10 show the structure of the fourth embodiment of the present invention, FIG. 9 is a perspective view of the dust suction unit, and FIG. 10 is a longitudinal sectional view of FIG.

The fourth embodiment is identical in configuration to the first embodiment except for the dust suction unit 410. Therefore, the configuration of the dust suction unit 410 will be described.

The dust suction unit 410 is connected to a nozzle 411, one end of which is connected to the suction pipe 30 to directly generate a suction force, and a motor discharge pipe 116 connected to the discharge port of the motor 23, It is configured to include a vortex generator 415 for generating a vortex in the air sucked into the nozzle 411 by using the air discharged from the motor (23).

The vortex generator 415 generates the vortex by using the air discharged from the motor 23. In addition, the vortex generator 415 has a cylindrical vortex guider 417 formed to be inserted into the center of the nozzle 411 and the wind discharged from the motor 23 to be introduced into the vortex guide 417. The vortex generation inlet 418 and the motor discharge pipe 116 connecting the discharge port of the motor 23 and the vortex generation inlet 418 is formed so that it can be configured. The vortex generating inlet 418 is formed obliquely from the outside of the side wall of the vortex guider 417 into the wind flows through the vortex generating inlet 418 is vortex along the inner surface of the vortex guider 417 To form.

The vortex guide 417 has a lower portion sealed by a lower surface 421, and an upper surface thereof is opened except for a plurality of ribs 419 which fix the nozzle 411 to the vortex guide 417. It is composed of a vortex guide discharge port 450. In addition, the vortex guide 417 has a vortex guide inlet 451 is formed on the bottom surface. The suction port 451 is formed to coincide with the hollow of the nozzle 411.

In addition, the vortex generation inlet 418 is preferably formed at the lower end of the vortex guider (417).

The nozzle 411 includes an upper nozzle 412 connected to the rib 419, and a lower nozzle 413 formed through the lower surface 421 of the vortex guide 417. 412 and the lower nozzle 413 are formed to have a predetermined gap in the air introduced into the lower nozzle 413 to be affected by the vortices generated by the vortex guide 417.

The operation of the fourth embodiment of the present invention will be described below.

However, since the operation of the fourth embodiment differs only in the dust suction unit 410 from the first embodiment, the dust suction unit 410 will be described.

Air introduced into the vortex guider 417 through the vortex generating inlet 418 flows along the inner surface of the vortex guider 417 to generate vortices. The vortex rises while rotating on the bottom surface 421 of the vortex guider 417 and is discharged through the top surface of the vortex guider 417. In addition, the air sucked through the lower nozzle 413 is increased by the vortex generated by the vortex guider 417 is sucked into the dust collector 412 through the upper nozzle 411.

As described above, in the dust suction unit 410 of the fourth embodiment, the air introduced into the vortex guider 417 is discharged to the upper surface of the vortex guider 417, so that dust scattered by being discharged to the lower surface does not occur. Do not.

11 and 12 show the structure of the fifth embodiment of the present invention, FIG. 11 is a longitudinal sectional view of the dust suction unit, and FIG. 12 is a cross sectional view of FIG.

The fifth embodiment is identical in configuration to the first embodiment except for the dust suction unit 510. Therefore, the configuration of the dust suction unit 510 will be described.

The dust suction unit 510 may include a nozzle 511 having one end connected to the suction pipe 30 to generate a direct suction force, and a vortex generator 515 for generating a vortex in the air sucked into the nozzle 511. And a dust scattering unit configured to scatter dust attached to the sea toward the nozzle 511 by using a part of the air introduced into the vortex generator 515.

The vortex generator 515 generates the vortex by using the air discharged from the motor 23. In addition, the vortex generator 515 may enter the cylindrical vortex guider 517 and the wind discharged from the motor 23 to the inside of the vortex guide 517 so that the nozzle 511 is inserted into the center thereof. And a motor discharge pipe 116 connecting the vortex generating inlet 518 and the outlet of the motor 23 and the vortex generating inlet 518 to be formed. The vortex generating inlet 518 is formed obliquely from the outside of the side wall of the vortex guider 517 to the wind flowing through the vortex generating inlet 518 vortex along the inner surface of the vortex guider 517 To form.

The lower surface of the vortex guider 517 is opened to allow the air introduced through the vortex generation inlet 518 to flow out to form the vortex guide discharge port 571.

The dust scattering portion is formed of a scattering ring 552 formed so that the vortex guider 517 is inclined downward from the bottom to the inside. The scattering ring 552 scatters dust positioned below the dust suction unit 510 to facilitate suction by the nozzle 511. In addition, the vortex guide 517 has a boundary ring 551 that distinguishes the vortex 561 from the scattering 562 at the upper end of the scattering ring 552 so that the vortex 562 can be generated well. It is fixed at. The boundary ring 551 has a ring-shaped plate shape, and the hollow is installed to coincide with the hollow of the nozzle 511 and is spaced apart from the lower end of the nozzle 511 by a predetermined degree. In addition, the inner side of the vortex guider 517 is fixed by a plurality of fixing ribs 553.

The operation of the fifth embodiment of the present invention will be described below.

However, since the operation of the fifth embodiment differs only in the dust suction unit 510 from the first embodiment, the dust suction unit 510 will be described.

The air introduced into the vortex guider 517 through the vortex generating inlet 518 flows along the inner surface of the vortex guider 517 to generate the vortex 561. The vortex 561 meets in the space between the suction flow 563 formed by the suction force of the nozzle 111 and the end of the nozzle 511 and the boundary ring 551 to absorb the suction force of the nozzle 111. Increase In addition, the scattering stream 562 formed along the scattering ring 562 scatters dust on the floor toward the nozzle 511 so that the nozzle 111 can easily inhale dust.

Although the preferred embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope described in the claims.

According to the present invention as described above it can be expected the following effects.

First, the present invention generates vortices in the dust suction unit by using the air discharged from the motor to increase the suction power, thereby increasing the efficiency of the vacuum cleaner without using a separate power.

In addition, by providing an additional guide wall, the vortex generated by the vortex guider is formed to be extended to increase the suction distance.

And, by forming the lower end of the additional guide wall obliquely, the user can clean the dust suction inclined at an angle, it is easy to use.

On the other hand, by configuring the air introduced into the vortex guider to be discharged to the upper surface of the vortex guider, it is possible to prevent the scattering of dust generated by the discharge to the lower surface.

On the other hand, by providing a scattering ring, dust attached to the floor can be scattered to the nozzle side to easily suck the dust attached to the floor.

Claims (3)

In the vacuum cleaner comprising a dust suction unit, a dust collector connected to the suction pipe from the dust suction unit to collect the sucked dust, and a motor for generating a suction force to the dust suction unit, the dust suction unit A nozzle connected at one end to the suction pipe to generate a direct suction input; A vortex generator which is connected to a motor discharge pipe connected to the discharge port of the motor, generates vortex in the air sucked into the nozzle by using the air discharged from the motor, and discharges the air to the upper end; Vacuum cleaner comprising a. The method of claim 1, The nozzle has a pipe shape; The vortex generator includes: a vortex guider formed with the nozzle inserted in the center, and having a vortex guider inlet formed at a lower surface thereof in accordance with the hollow of the nozzle; The inlet is formed obliquely from the outside of the side wall so that the wind discharged from the motor is formed on the side wall of the vortex guider to flow into the inside of the vortex guider, and the wind can be introduced in the tangential direction of the vortex guider. A vortex generation inlet; An upper discharge port formed on an upper surface of the vortex guider; Vacuum cleaner comprising a. The method of claim 2, wherein the nozzle A lower nozzle formed by fixing a lower end to the vortex guide inlet; An upper nozzle installed axially spaced apart from the lower nozzle and having one end connected to the suction pipe; Vacuum cleaner comprising a.