KR20190122127A - Airborne Dust Cleaner with vortex vacuum generator at the inlet - Google Patents

Abstract

The present invention relates to an airborne dust cleaner equipped with a vortex vacuum generator at an inlet, which comprises: a case having an inlet on one side and an outlet on the other side, and having a space therein; a vortex vacuum generator installed in the inlet, and configured to collect fine dust by expanding and forming a low pressure zone of a doughnut-shaped vortex around the inlet; and a filter unit installed in the outlet to filter fine dust collected via the vortex vacuum generator.

Description

Airborne Dust Cleaner with vortex vacuum generator at the inlet

The present invention relates to a floating dust cleaner, and more particularly, to a floating dust cleaner having a vortex vacuum generator at an inlet.

A variety of products are used to improve the increasingly serious indoor air quality environment. Typically, vacuum cleaners are used to clean the dust off the floor, and air cleaners are used to clean indoor air.

However, contrary to the general idea, the air cleaner has a weak dust absorption input, so that the filtered air is supplied to the room through a blower fan rather than the function of removing the dust in the air, thereby remaining in the role of lowering the indoor dust concentration by the dilution action.

The weak dust absorption input of air cleaners is due to the fundamental limitations of general fans, which serve to draw air and dust into the equipment. In order for the flow of air to carry dust, the suction velocity of the fan-generated air must be greater than the gravity's gravitational force (sink force) and inertia (force propagation in the direction). However, if the suction flow rate of all the fans falls only by the diameter of the fan, the flow rate drops below 10%. Thus, dust farther than the fan's diameter will not allow the fan to suck at all.

1 is a diagram showing a suction flow rate distribution of a general fan, J.M. Dalla Valle used the following equation to determine that at a distance away from the inlet by the diameter of the inlet, the flow rate of the airflow was only 7.4% of the inlet inlet flow rate (velocity Contours-plain circular opening-% of opening velocity; American Conference of Governmental Industrial Hygienists (ACGIH): Industrial Ventilation Manual, 23rd Edition).

Where Vx is the flow rate at point x, Vf is the inlet inlet flow rate, x is the separation distance from the inlet, and d is the diameter of the inlet. Therefore, the flow rate at one time of the inlet diameter d, that is, at the point x = d is Vx = 0.074 Vf, that is, 7.4% of the inlet inlet flow rate Vf.

In addition, all air cleaners have a structure in which various filters (pre-filter, deodorizing filter, hepa filter) are placed in front of the fan, and thus, there is a structural limitation that the dust suction power of the fan is further lowered due to the differential pressure of the filters. Therefore, there is a problem that heavy particles such as allergens do not flow to the suction port and fall down.

In order to solve this problem, efforts have been made to increase the air volume of the fan provided in the air cleaner. However, as the air blowing amount of the fan increases, the power consumption is excessively increased, and the vibration and noise generated from the fan increase, which lowers the reliability of the product. There was a problem.

In addition, a conventional air cleaner is provided with an inlet port on the front side and an outlet port is provided on the upper side, so that the contaminated air around the air cleaner does not flow through the inlet port and ascends toward the ceiling along the flow of air discharged from the outlet port. There is a problem that falls back to the ground. This problem is more apparent when the discharge speed of the air due to the high speed rotation of the fan is faster.

The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide an air purifying device in which a fine dust collecting region is expanded as compared with the conventional art.

Another object of the present invention is to provide an air purifying device having low vibration and noise.

Still another object of the present invention is to provide an air purifying device which is compact in size and easy to carry and install.

An object of the present invention described above is a case having a suction port is formed on one side and the discharge port is formed on the other side, the case having a space therein; A vortex vacuum generator installed at the suction port and collecting the fine dust by expanding a low pressure band of a donut-shaped vortex around the suction port; And a filter unit installed at the discharge port and filtering the fine dust collected through the vortex vacuum generator, by providing a floating dust cleaner having a vortex vacuum generator at the suction port.

According to one feature of the present invention, the case may include a pedestal in the form of a circular plate supported on the ground, and a body supported on the pedestal and having a space formed therein.

According to another feature of the invention, the body is a cylindrical body portion that is supported on the upper side of the pedestal, the first protrusion is formed to project upwardly inclined upward from one side of the upper end of the body portion, and the other side from the upper end of the body portion It may include a second protrusion protruding obliquely.

According to still another feature of the present invention, the first and second protrusions have a hollow hollow shape and have a circular cross-sectional shape. The suction hole is formed at the end of the first protrusion, and the discharge hole is at the end of the second protrusion. Can be formed.

According to another feature of the invention, the vortex vacuum generating device, a swirler fan having a plurality of fins vertically formed on the annular rotating plate having a through portion in the center, a suction fan disposed at the rear end of the swirler fan, and the A rear end of the suction fan may include a drive motor driving the swirler fan and the suction fan.

According to another feature of the invention, the swirler fan, a circular band member formed along the inner circumferential surface of the rotating plate, the coupling portion is formed in the center of the through portion coupled to the drive shaft of the drive motor, the coupling It may include a connecting rod formed radially from the portion to the inner peripheral surface of the circular band member.

According to another feature of the present invention, the vortex vacuum generator, the side wall is formed to be inclined forward and outward along the rear edge, the guide flange is formed to extend outward from the front end of the side wall It may further include a bell mouse formed at the front end of the swirler fan.

According to another feature of the present invention, the vortex vacuum generator may further include a suction fan housing in which a flow path is formed on a side wall to accommodate the suction fan therein and guide the air discharged from the suction fan to the rear. have.

According to another feature of the present invention, the suction fan housing may include a cylindrical housing body having a rear opening and an opening penetrating through the front end thereof, and a bottom plate having a circular plate shape coupled to a rear end of the housing body. Can be.

According to another feature of the present invention, the suction fan housing further includes a pair of guide parts each protruding spirally so as to gradually decrease in width and height along the circumferential direction to face one side and the other side of the housing main body. can do.

According to still another feature of the present invention, a flow path having a cross-sectional area gradually decreasing in the circumferential direction is partitioned by partition walls in the guide part, and an inlet of the flow path may communicate with a space part inside the housing body.

According to another feature of the invention, a pair of guide holes may be formed through the bottom plate to correspond to the pair of guide portion.

According to another feature of the invention, the housing body may include a support portion protruding along the periphery of the opening, and a plurality of coupling bosses protruding along the outer periphery of the support.

According to another feature of the invention, an LED substrate mounted with an LED may be coupled between the support and the coupling boss along the circumference of the support.

According to another feature of the invention, the LED may change the emission color according to the measurement value of the fine dust sensor installed in the case.

According to another feature of the invention, the filter unit may include a filter housing coupled to the inside of the discharge port, and a filter member embedded in the filter housing.

According to another feature of the invention, it may further include a guide tube installed inside the case, one end is coupled to the rear end of the vortex vacuum generator and the other end is coupled to the front end of the filter unit.

According to another feature of the invention, it may further include a front grill coupled to the suction port disposed in front of the vortex vacuum generating device, and a prefilter coupled to one surface of the front grill.

According to another feature of the invention, the fine dust sensor is installed on one side of the space portion, and may be further provided on one side of the suction port and the LED of the emission color is changed according to the measured value of the fine dust sensor.

According to another feature of the invention, it may further include a USB charging terminal provided on one side of the case.

According to the floating dust cleaner according to the present invention, the low pressure band of the donut-shaped vortex is formed around the suction port, and thus the fine dust collecting region is expanded as compared with the conventional one.

In addition, according to the floating dust cleaner according to the present invention, it is possible to remove the fine dust in the room with low power and low noise.

In addition, according to the floating dust cleaner according to the present invention, it is lightweight and easy to carry and install, there is an advantage that can be conveniently used on a desk or table as a compact size.

In addition, according to the floating dust cleaner according to the present invention, since the emission color of the LED changes according to the fine dust concentration, it is possible to check the air quality in the room in real time.

1 is a diagram showing a simulation result of the suction flow rate distribution of a typical fan.
2 is a perspective view of a floating dust cleaner according to an embodiment of the present invention.
3 is a left side view of the floating dust cleaner according to an embodiment of the present invention.
4 is a right side view of the floating dust cleaner according to an embodiment of the present invention.
5 is a partial exploded view of the floating dust cleaner according to an embodiment of the present invention.
6 is a cross-sectional view of the floating dust cleaner according to an embodiment of the present invention.
Figure 7 is an exploded perspective view of the floating dust cleaner according to an embodiment of the present invention.
8 is a rear view of the housing main body according to an embodiment of the present invention.
9 is a flow simulation result of the ambient air during operation of the floating dust cleaner according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the embodiments described below are merely to describe in detail enough to be able to easily carry out the invention by those skilled in the art to which the present invention pertains, and thus the protection scope of the present invention is limited. It does not mean. In describing various embodiments of the present invention, the same reference numerals will be used to refer to elements having the same technical features.

Example

2 is a perspective view of the floating dust cleaner according to an embodiment of the present invention, Figure 3 and Figure 4 is a side view of the floating dust cleaner according to an embodiment of the present invention.

2 to 4, the floating dust cleaner (hereinafter referred to as 'floating dust cleaner') 100 having a vortex vacuum generator in the suction port according to an embodiment of the present invention, the suction port 421 and The case 200 includes a discharge port 431, a vortex vacuum generator 500 installed in the suction port 421, and a filter unit 700 installed in the discharge port 431.

The case 200 includes a pedestal 300 in the form of a circular plate supported on the ground, and a body 400 supported on the pedestal 300 and having a space formed therein. In order to stably support the body 400, the width of the pedestal 300 is larger than the bottom width of the body 400.

Body 400 is a cylindrical body portion 410 that is supported on the upper side of the pedestal 300, the first protrusion 420 is formed to protrude inclined upward from the upper end of the body portion 410 to one side, and the body portion ( The second protrusion 430 is formed to protrude obliquely upward from the top of the 410 to the other side.

The USB charging terminal 440 is provided at the front lower end of the body part 410, and the connector terminal 450 for connecting the power cable is provided at the lower rear part.

On one side of the lower end of the body portion 410, in order to control the operation of the floating dust cleaner 100, the power button 461 and the operation mode selection button 462 and the LED operation button 463 operating in a touch (touch) method Is provided. For example, the user may turn on / off the power of the floating dust cleaner 100 by touching the power button 461. Alternatively, by touching the operation mode selection button 462, one of the operation modes divided into three stages may be selected or an automatic mode may be selected according to the rotation speed of the fan. If the auto mode is selected, the power ON / OFF and fan rotation speed are automatically adjusted according to the air quality in the room. On the other hand, the floating dust cleaner 100 according to an embodiment of the present invention is to change the emission color of the LED 581 installed on the inlet 421 side according to the air quality of the room, if necessary, the user LED operating button 463 Touch to turn on / off this LED 581. In addition, the LED operation button 463 may also serve as a warning light to inform the filter replacement time, for example, by red light emission.

A plurality of through holes 470 are formed in the lower end of the other side of the body 410, and a fine dust sensor 910 for detecting fine dust is installed in the inner space of the through hole 470. According to the measurement value of the fine dust sensor 910, the light emission color of the LED 581 of the suction port 421 and the fan rotation speed according to the automatic mode selection are changed.

The first protrusion 420 and the second protrusion 430 have a hollow hollow shape and have a circular cross-sectional shape. The body portion 410 and the first protrusion 420, the body portion 410 and the second protrusion 430, and the first protrusion 420 and the second protrusion 430 are naturally connected to the outer surface. In addition, an inlet 421 through which fine dust flows is formed at an end of the first protrusion 420, and an outlet 431 to discharge the filtered air while passing through the filter unit 700 at the end of the second protrusion 430. ) Is formed.

5 is a partial exploded view of the floating dust cleaner according to an embodiment of the present invention.

As shown in FIG. 5, the body 400 may be formed by a combination of the first body 401 and the second body 402 which are formed symmetrically, and the first body 401 and the second body 402. ) May be coupled to each other by fasteners such as bolts, for example.

In addition, the floating dust cleaner 100 according to an embodiment of the present invention includes a vortex vacuum generator 500 installed in the suction port 421, and a filter unit 700 installed in the discharge port 431. More specifically, the vortex vacuum generator 500 is installed in the interior of the first protrusion 420 adjacent to the suction port 421, and is adjacent to the discharge port 431 in the second protrusion 430. 700 is installed.

The vortex vacuum generator 500 includes a suction fan 530 that sucks external air while rotating by the driving motor 540. Therefore, the fine dust in the room is introduced into the space inside the body 400 through the inlet 421, the filtered air is supplied back to the room through the discharge port 431 through the filter unit 700.

Hereinafter, the configuration of the vortex vacuum generator and the filter unit will be described in detail with reference to FIGS. 6 and 7.

6 is a cross-sectional view of the floating dust cleaner according to an embodiment of the present invention, Figure 7 is an exploded perspective view of the floating dust cleaner according to an embodiment of the present invention.

6 and 7, the vortex vacuum generator 500 includes a swirler fan 510, a suction fan 530 disposed at a rear end of the swirler fan 510, and a rear end of the suction fan 530. It is disposed in the drive motor 540 for driving the swirler fan 510 and the suction fan 530.

At this time, the swirler fan 510 includes an annular rotating plate 511 having a through portion 512 in the center, a plurality of pins 513 formed vertically on the rotating plate 511, and an inner circumferential surface of the rotating plate 511. A circular band member 514 formed vertically along the coupling part, a coupling part 515 formed at the center of the through part 512 and coupled to the driving shaft 541 of the driving motor 540, and from the coupling part 515. Connection rod 516 formed radially to the inner peripheral surface of the circular band member 514.

A bell mouth 520 is installed to surround the swirler fan 510. The bell mouse 520 has a cylindrical shape in which the diameter of the front end portion is larger than the diameter of the rear end portion. A coupling flange 521 protrudes to have a predetermined width inwardly along the rear edge of the bell mouse 520, and a sidewall 522 having a curved surface inclined outwardly is extended. At the front end of the side wall 522, the guide flange 523 is extended to the outside.

The bell mouse 520 is installed in such a manner that the side wall 522 surrounds the outside of the fin 513 of the swirler fan 510. That is, when the swirler fan 510 is mounted in the bell mouse 520, the guide flange 523 is formed at a point that is equal to or greater than the front end of the pin 513 along the direction of the central axis of the swirler fan 510. This is to allow the airflow pushed out when the swirler fan 510 rotates to flow along the sidewall 522 of the bell mouse 520 by the Coanda effect, and the airflow flowing through the sidewall 522. Is guided out of the bell mouse 520 along the guide flange 523 to form a vortex.

That is, by the rotation of the swirler fan 510, the airflow flows toward the outside of the swirler fan 510 and returns to form a low pressure valley, and a kind of donut type low pressure zone is formed at the outer periphery of the swirler fan 510. Due to the low pressure zone, the center of the donut-shaped vortex is also formed with low pressure, so that the intake air flow appears toward the center of the swirler fan 510. However, only the intake airflow by the rotation of the swirler fan 510 does not achieve the desired level of fine dust suction effect, and by driving the suction fan 530 at the rear end of the swirler fan 510 as in the present invention, Need to make inhalation airflow.

The suction fan 530 may be formed in the form of a centrifugal fan such as a sirocco fan, or an axial fan such as a propeller fan. As the suction fan 530 rotates together with the swirler fan 510, the donut-type cyclone has a circular motion, and the whirlwind allows the fine dust of a wide range to be collected. The center of the whirlwind is a very low pressure band, and the airflow sucked by the suction fan 530 flows through the central portion of the swirler fan 510 at high speed and flows into the case 200.

The drive motor 540 is disposed behind the suction fan 530, and the drive shaft 541 of the drive motor 540 extends through the suction fan 530 to the swirler fan 510. That is, the suction fan 530 and the swirler fan 510 are installed to rotate at the same time by the driving motor 540.

The suction fan 530 is rotatably received in the suction fan housing 550, and the suction fan housing 550 is inserted into and mounted in the first protrusion 420. The suction fan housing 550 includes a housing main body 560 having an open rear side, and a bottom plate 567 having a circular plate shape coupled to a rear end of the housing main body 560, and the driving motor 540 includes a motor bracket ( 542 is coupled to the back of the bottom plate 567.

The housing body 560 is generally cylindrical in shape, and an opening 561 is formed through the center of the front end thereof. In addition, the support 562 protrudes forward along the periphery of the opening 561. When the swirler fan 510 is coupled to the front of the housing body 560, the rear end of the circular band member 514 of the swirler fan 510 is formed. It is accommodated inside the support part 562.

On the other hand, one side and the other side of the side wall of the housing main body 560, a pair of guide portions 564, the width and height gradually decrease in the circumferential direction are formed to protrude in a spiral respectively facing each other. In addition, a pair of guide holes 568 are formed through the bottom plate 567 so as to correspond to the pair of guide portions 564.

FIG. 8 is a rear view of the housing main body according to an embodiment of the present invention, and as shown in FIG. 8, a flow path 565 having a sectional area gradually decreasing along the circumferential direction is formed in each guide part 564. 566). In addition, the inlet of the flow path 565 of the guide part 564 communicates with the space inside the housing body 560, and the guide hole 568 formed through the bottom plate 567 when the bottom plate 567 is coupled is a flow path ( 565).

The guide part 564 and the guide hole 568 formed in the suction fan housing 550 in this way, when the suction fan 530 is composed of a centrifugal fan such as a sirocco fan, the radially outer side of the suction fan 530 It is for guiding the airflow discharged toward the rear side of the suction fan housing 550. In addition, since the flow path 565 inside the guide part 564 is formed in a form in which the cross-sectional area gradually decreases along the circumferential direction, the air flow passing through the flow path 565 of the guide part 564 is sucked through the guide hole 568. It is quickly discharged to the rear of the fan housing 550, and thus it is possible to prevent the suction force decrease due to the accumulation of airflow discharged from the suction fan 530.

6 and 7, the rear end of the bell mouse 520 is coupled to the front end of the suction fan housing 550. In more detail, a plurality of coupling bosses 563 protrude along the outer circumference of the support part 562 of the housing body 560, and the coupling flange 521 of the bell mouse 520 and the housing body 560 are formed. By fastening fasteners such as bolts through the coupling boss 563, the bell mouse 520 and the suction fan housing 550 are coupled to each other. In this case, in order to prevent leakage of airflow discharged from the swirler fan 510, a ring-shaped gasket 570 is coupled to the front surface of the coupling flange 521.

Meanwhile, the LED substrate 580 is coupled between the support part 562 and the coupling boss 563 along the circumference of the support part 562 of the housing main body 560. The LED substrate 580 may be formed in a circular shape, and as another example, a plurality of arc-shaped LED substrates 580 may be coupled along the circumference of the support 562. The light emitting color of the LED 581 mounted on the LED substrate 580 changes according to the measurement value of the fine dust sensor 910, and the user projects the LED 581 projecting from the LED 581 and leaking toward the suction port 421. By checking the luminous color of the indoor air quality can be intuitively known.

A front grill 590 is detachably coupled to the front end of the bell mouse 520. The front grill 590 is coupled to the grid network 591 having a plurality of fine holes on one surface by bonding or fusion, and is disposed in front of the vortex vacuum generator 500 to remove foreign substances such as dust when inhaling fine dust. It functions as a pre-filter that filters first.

The air sucked into the body 400 by the vortex vacuum generator 500 is discharged to the rear of the suction fan housing 550, and is discharged through the filter unit 700 installed in the second protrusion 430. 431 is supplied back to the room.

At this time, in order to guide the air flow discharged to the rear of the suction fan housing 550 toward the second protrusion 430 in which the filter unit 700 is installed, the vortex vacuum generator 500 and the filter unit inside the body 400. A guide tube 600 connecting the 700 may be installed between the first protrusion 420 and the second protrusion 430.

 For example, the guide tube 600 may be formed in the form of a pipe bent at a predetermined angle and the front and rear both ends, the front end of the guide tube 600 may be coupled to the rear plate 567 rear surface of the suction fan housing 550. have. The rear end of the guide tube 600 may be bent at a predetermined angle to extend in the direction of the second protrusion 430, and the rear end of the guide tube 600 may be in close contact with the front end of the filter housing 710 to be described later. have. In this case, the air flow introduced into the guide tube 600 through the guide hole 568 of the bottom plate 567 flows in the direction of the filter unit 700 along the guide tube 600.

The filter unit 700 includes a filter container 710 and at least one filter member 720 embedded in the filter container 710, and collects dust collected by the vortex vacuum generator 500. It acts as a filter.

The filter housing 710 is inserted into the inside of the second protrusion 430 as a cylindrical shape with the front and rear both ends open, wherein the front end of the filter housing 710 is the aforementioned guide tube 600 to prevent the leakage of airflow It is preferable to make it adhere to the rear end of the The filter member 720 filters out fine particles such as fine dust, tobacco smoke, pollen, animal keratin, house dust mites, molds, bacteria, viruses, and the like, for example, an activated carbon filter 721 and a HEPA filter. ) 722 may be stacked in the filter container 710 in turn.

The rear grill 800 is disposed at the rear end of the filter unit 700, and the rear grill 800 is coupled to the rear end of the second protrusion 430.

On the other hand, the upper side of the pedestal 300 is provided with a controller 900 in the form of a PCB substrate, the controller 900 is a power ON / OFF, the rotational speed control of the drive motor 540, LED ON / OFF and emission color control, It serves as a warning light display, communication with the fine dust sensor 910.

2 to 8, the operation of the floating dust cleaner 100 according to an embodiment of the present invention will be described in detail.

First, the user touches the power button 461 to supply power to the floating dust cleaner 100, and touches the operation mode selection button 462 to select the operation mode.

The driving motor 540 is operated by the power supply, and the swirler fan 510 and the suction fan 530 rotate at the same time. At this time, the rotation speed of the drive shaft 541 of the drive motor 540 is adjusted according to the selected driving mode, and the emission color of the LED 581 of the suction port 421 is changed according to the measured value of the fine dust sensor 910. For example, it can emit light in four stages of blue-green-orange-red according to the indoor air quality.

The airflow pushed out by the rotation of the swirler fan 510 flows along the side wall 522 of the bell mouse 520 and the guide flange 523 by the Coanda effect and strongly blows out of the bell mouse 520. In the periphery of the suction port 421, a vortex of a donut-type low pressure band is formed.

At this time, the low pressure is also formed in the center of the donut-shaped vortex so that the intake air flows toward the center of the swirler fan 510, and the suction fan 530, which rotates simultaneously with the swirler fan 510, adds a driving force to the intake air and strengthens it. Do it. In other words, by the rotation of the swirler fan 510 and the suction fan 530, a strong suction air flow is formed through the swirler fan 510 and sucked into the suction fan 530, and the surrounding fine dust is carried in the suction air stream. It is to be quickly brought into the suction fan (530). In addition, the vortex of the donut-type low-pressure bar that extends to the periphery of the suction port 421 makes it possible to collect and suck dust in a wider area than the existing floating dust cleaner.

Air flow sucked through the swirler fan 510 is discharged radially outward of the suction fan 530 and flows along the flow path 565 of the guide part 564 of the suction fan housing 550, and guides the guide hole 568. It is discharged to the guide tube 600 through. Thereafter, the airflow flowing along the guide tube 600 passes through the filter member 720 to remove fine dust, and cleanly filtered air is supplied back to the room through the discharge port 431.

9 is a result of simulating the flow of ambient air during the operation of the floating dust cleaner according to an embodiment of the present invention, by the swirler fan 510 to form a donut-shaped vortex in the periphery of the inlet, the fine dust collecting region is conventional You can see that it expands compared to The central portion of the donut-shaped vortex is a low-pressure region, the surrounding air is sucked in with the fine dust, the suction fan 530 serves to strengthen the fine dust suction force.

Although the embodiments of the present invention have been described above, it will be understood by those skilled in the art that various modifications may be made without departing from the scope of the claims of the present invention.

100: floating dust cleaner 200: case
300: pedestal 400: body
420: first protrusion 421: suction port
430: second projection 431: discharge port
440: USB charging terminal 450: Connector terminal
461: power button 462: operation mode selection button
463: LED operation button 500: Vortex vacuum generator
510: Swallower Fan 520: Bellemouth
530: suction fan 540: drive motor
550: suction fan housing 560: housing body
564: guide portion 565: euro
567: bottom plate 568: guide hole
570: Gasket 580: LED substrate
590 front grill 600 guide tube
700: filter unit 710: filter housing
720: filter member 800: rear grille
900: controller 910: fine dust sensor

Claims (10)

A case having a suction port formed at one side and a discharge port formed at the other side, and having a space part therein;
A vortex vacuum generator installed at the suction port and collecting the fine dust by expanding a low pressure band of a donut-shaped vortex around the suction port; And
And a filter unit installed at the discharge port and filtering the fine dust collected through the vortex vacuum generator, and having a vortex vacuum generator at the suction port. The method according to claim 1,
The case includes a pedestal in the form of a circular plate supported on the ground, and a body supported on the pedestal and having a space formed therein, wherein the body is a cylindrical body portion supported on the upper side of the pedestal, and the body Floating dust cleaner equipped with a vortex vacuum generator in the suction port, characterized in that it comprises a first protrusion which is formed to be inclined upwardly to one side from the top of the portion, and a second protrusion which is formed to be inclined upwardly to the other side from the top of the body portion . The method according to claim 2,
The first and second protrusions have a hollow hollow shape and have a circular cross-sectional shape, wherein the suction hole is formed at the end of the first protrusion, and the discharge hole is formed at the end of the second protrusion. Airborne dust cleaner with vortex vacuum generator. The method according to claim 1,
The vortex vacuum generator includes: a swirler fan having a plurality of pins vertically formed on an annular rotating plate having a penetrating portion at its center, a bell mouse surrounding the swirler fan, a suction fan disposed at a rear end of the swirler fan, And a driving motor disposed at a rear end of the suction fan and driving the swirler fan and the suction fan. The floating dust cleaner having a vortex vacuum generator at the suction port is provided. The method according to claim 4,
The vortex vacuum generator further includes a suction fan housing accommodating the suction fan therein and having a flow path formed in a side wall to guide the air discharged from the suction fan to the rear. Floating dust cleaner equipped with a device. The method according to claim 5,
The suction fan housing has a cylindrical housing main body having a rear opening and an opening penetrating through the front end thereof, and spirally protruding from the one side and the other side of the housing main body so as to gradually decrease in width and height along the circumferential direction. And a pair of guide parts formed and a bottom plate of a circular plate shape coupled to the rear end of the housing main body. The method according to claim 6,
In the guide portion, a flow passage whose cross-sectional area gradually decreases along the circumferential direction is partitioned by partition walls, and the inlet of the flow passage communicates with the space portion inside the housing body, and corresponds to the pair of guide portions. Floating dust cleaner equipped with a vortex vacuum generator in the suction port, characterized in that the guide hole is formed through the plate. The method according to claim 7,
The housing body includes a support part protruding along the periphery of the opening, and a plurality of coupling bosses protruding along the outer periphery of the support part, and an LED is provided between the support part and the coupling boss along the support part. Mounted LED substrate is coupled, the LED is characterized in that the emission color is changed according to the measurement value of the fine dust sensor installed in the case, the floating dust cleaner equipped with a vortex vacuum generator in the suction port. The method according to claim 1,
It is installed inside the case, characterized in that it further comprises a guide tube is coupled to the rear end of the vortex vacuum generator and the other end is coupled to the front end of the filter unit, floating inlet having a vortex vacuum generator Dust cleaner. The method according to claim 1,
Further comprising a fine dust sensor installed on one side of the space portion, and the LED installed on one side of the suction port and the emission color is changed according to the measured value of the fine dust sensor, the suction port is provided with a vortex vacuum generator Floating Dust Cleaner.

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