KR100643695B1 - Cyclonic cleaner - Google Patents

Abstract

A cyclone cleaner is provided to prevent the echo of the air from occurring and reduce the noise by arranging the porous member between the dust collecting unit and the cyclone chamber. A cyclone cleaner is composed of: a housing(20) containing outer and inner containers(21,22); a first cyclone unit(30) installed in the inner container to firstly filter the dust and the impurities contained in the sucked air; and a second cyclone unit(40) mounted in the outer container to secondly filter the dust and the impurities contained in the air passing through the first cyclone unit. The second cyclone unit has plural cyclone chambers(31,41) and dust collecting units(32,42). A porous member(60) is arranged between the dust collecting unit and the cyclone chamber. The porous member is formed as a plate having plural holes.

Description

Cyclone Cleaner

1 is a perspective view showing the appearance of a cyclone cleaner according to the present invention.

Figure 2 is a longitudinal sectional view showing the structure of the cyclone separator according to the present invention shown in FIG.

FIG. 3 is an exploded perspective view taken along line III-III of FIG. 2 and illustrates a porous member provided between the cyclone chamber and the dust collecting unit.

4 is a view showing another embodiment of the porous member according to the present invention.

5 is a graph for explaining the effect of the porous member according to the present invention.

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

10. Cyclone Separator 20. Housing

21..outer container 22..inner container

1st, 2nd cyclone unit 31, 41. 1st, 2nd cyclone chamber

32, 42. 1st, 2nd collecting part 50 .. Upper cap

52.Guide member 60: Porous member

The present invention relates to a cyclone cleaner having a cyclone separator to separate dust and foreign matter contained in the air by using a centrifugal force.

In general, the vacuum cleaner is a mechanism for cleaning the room by separating the dust and foreign matter contained in the air sucked after the air by using the suction power of the blower through the filter.

Recently, instead of installing a filter that separates dust and foreign substances inside the vacuum cleaner, a cyclone separator is installed to generate swirl air from the sucked air, and the dust and foreign matter are separated from the air by using the centrifugal force of the swirl air. Cyclone cleaners have been developed to make it easier to empty the separated dust and debris.

For example, WO02 / 067755 discloses a cyclone cleaner having a cyclone separator for arranging a plurality of cyclone chambers for generating swirling airflow in parallel and separating dust and foreign matter from the inhaled air using a cyclone action.

However, in the conventional cyclone cleaner, since a plurality of cyclone chambers installed therein have the same size and shape and are in communication with each other, large flow noise is generated due to the overlapping noise generated in each cyclone chamber. Will occur.

In addition, such a conventional cyclone cleaner has a structure in which a plurality of cyclone chambers communicate with one dust bin, so that the sound generated in each cyclone chamber is echoed in the dust bin and noise is amplified.

The present invention is to solve the above-mentioned problems of the prior art, an object of the present invention is to provide a cyclone cleaner to reduce the noise by preventing the noise generated in the plurality of cyclone chamber is overlapped and echoed. .

Cyclone cleaner of the present invention for achieving the above object is a housing including an outer container and the inner container, the first cyclone unit is installed in the inner container to filter the dust and foreign matter contained in the suction air primarily, and the outside A cyclone cleaner including a second cyclone unit installed in a container to secondaryly filter fine dust and the like contained in air that has passed through a first cyclone unit, wherein the second cyclone unit includes a plurality of cyclone chambers and dust collection units. It is characterized in that the porous member is provided therebetween.

In addition, the porous member is made of a plate formed with a plurality of through holes or a plate formed with a plurality of lattice holes, the size of the holes provided in the plate is characterized in that different from each other.

In addition, the porous member is characterized in that made of a sound absorbing material.

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

1 is a perspective view showing the appearance of a cyclone cleaner according to the present invention, the cyclone cleaner according to the present invention is an upright body (1) having a moving wheel (2) is installed at the bottom and the handle (3) is provided at the top, The foreign matter is collected and separated from the blower unit 4 installed at the lower part of the upright body 1, the suction unit 5 for guiding suction of air and foreign substances from the bottom, and the air flowing from the suction unit 4. It includes a cyclone separator 10 is detachably mounted to the body portion 1 in the upper portion of the blower (4).

The suction part 5 is coupled to the blower part 4 in the form of a duct provided with an air suction port 5a at an end adjacent to the floor of the indoor space. The suction part 5 is connected to an air inlet 11 (see FIGS. 2 and 3) of the cyclone separator 10 to be described later through a flow path (not shown) made of a conventional pipe, a hose, or the like. Therefore, air and foreign matter are introduced to the air inlet 11 through the air inlet 5a and the flow path.

Although the blower part 4 is not specifically shown in figure, the blower part consists of a blowing fan which generate | occur | produces a suction force, and the motor which drives this blowing fan. The blower 4 is connected to the discharge guide tube 13 extending downward from the air outlet 12 of the cyclone separator 10. Therefore, the foreign material filtered through the cyclone separator 10 is sucked to the blower (4) side through the discharge guide tube 13 is discharged back to the indoor space.

The cyclone separator 10 is detachably mounted to the body 1 provided at the upper portion of the blower 4. An internal structure of the cyclone separator 10 will be described in detail with reference to FIGS. 2 to 4.

2 is a longitudinal sectional view showing the structure of the cyclone separator 10 according to the present invention shown in FIG. As shown in FIG. 2, the cyclone separator 10 according to the present invention includes a housing 20 including a substantially cylindrical outer container 21 and an inner container 22, and installed in the inner container 22. The first cyclone unit 30 for the primary filtering of dust and foreign matter contained in the intake air, and the fine dust contained in the air passed through the first cyclone unit 30 is installed in the outer container 21 2 A second cyclone unit 40 for filtering by car is provided.

Here, the first cyclone unit 30 and the second cyclone unit 40 are communicated by the upper cap 50 that seals the upper portion of the housing 20, the upper cap 50 is the outer container of the housing 20 21) and each space of the inner container 22 is partitioned.

In addition, the air inlet 11 is provided on the side of the housing 20 to communicate with the first cyclone unit 30, the air outlet 12 is provided on the housing 20 to communicate with the second cyclone unit 40. .

The first cyclone unit 30 is provided in the first cylindrical cyclone chamber 31 of the substantially cylindrical shape installed in the upper center of the inner container 22, the lower portion of the inner container 22 by the first cyclone chamber 31 And a first collecting part 32 which collects dust and foreign matter which are separated from each other.

A plurality of through holes 33 are formed on the circumferential surface of the first cyclone chamber 31 having an open top. Therefore, the air introduced into the first cyclone unit 30 through the air inlet 11 is moved downwardly between the outer circumferential surface of the first cyclone chamber 31 and the inner circumferential surface of the inner container 22, and the first collecting portion ( In 32), dust and foreign matter contained in the air are separated by centrifugal force. Separated dust and foreign matters are accumulated in the first collecting unit 32, the air primarily filtered by the first cyclone unit 30 is introduced into the first cyclone chamber 31 through a plurality of through holes 33. To move upwards.

The second cyclone unit 40 includes a plurality of second cyclone chambers 41 disposed in the same shape and size along the circumferential direction on the upper portion of the outer container 21, and a second cyclone provided under the outer container 21. The second collecting part 42 collects the dust and foreign matter secondary separated by the chambers 41. The second collecting part 42 is a box communicating with each of the second cyclone chambers 41, and the bottom surface thereof is inclined as shown in FIG. 2 so that the centrifugal force is increased.

The plurality of second cyclone chambers 41 have a conical shape in which the cross-sectional area is reduced from the upper side to the lower side, and the air introduced into the second cyclone chamber 41 is at the upper center of each of the second cyclone chambers 41. Discharge port 43 is formed so as to exit. The air exiting the outlet 43 moves to the air outlet 12 through the inner space of the upper cap 50.

The upper cap 50 partitions each space of the outer container 21 and the inner container 22 of the housing 20, and communicates the first cyclone chamber 31 with the second cyclone chamber 41. A guide member 52 is provided.

The guide member 52 is positioned on the communication hole 24 of the upper cap 50 to guide the air that has passed through the first cyclone chamber 31 to each of the second cyclone chambers 41. 31, and an outlet portion 54 in communication with the second cyclone chamber 41, and has a substantially spiral shape (see FIG. 3) to increase the centrifugal force.

Therefore, the air introduced from the first cyclone unit 30 to the inlet portion 53 of the guide member 52 is moved to the outlet portion 54 while pivoting along the helical guide member 52 and then the second cyclone. The pivoting motion is moved downwardly along the inner circumferential surface of the chamber 41, and dust and foreign matter are filtered out in each of the second cyclone chambers 41 by centrifugal force.

That is, the separated dust and foreign matter fall downward and accumulate in the second collecting part 42, and the secondary filtered air moves upward and moves to the cyclone separator 10 through the outlet 43 of the second cyclone unit 41. The air outlet 12).

FIG. 3 is an exploded perspective view taken along line III-III of the cyclone separator 10 and illustrates a porous member 60 provided between the second cyclone chamber 41 and the second collecting portion 42. Here, the housing 20 consisting of the outer container 21 and the inner container 22 is a connection portion provided at approximately the middle point so as to easily empty the dust and foreign matter accumulated in the first and second collecting portions 32 and 42. It is formed so that it is separable into upper and lower parts by 25.

Referring to FIG. 3, the porous member 60 includes a plurality of second cyclone chambers 41 disposed in a circumferential direction, and one second collecting portion 42 provided to communicate with each of the chambers 41 below. Is installed on.

The porous member 60 is made of a conventional polypropylene injection molding, and has a plate 61 having a plurality of through holes 62 therein as shown in FIG. 3 or a lattice-shaped plate 63 as shown in FIG. 4. Is installed. Therefore, since the air passing through the second cyclone chamber 41 is prevented from directly colliding with the bottom surface of the second collecting part 42 by the porous member 60, the noise is reduced, and the through hole 62 is further reduced. As the flow rate decreases, the secondary flow of the second collecting part 42 formed to be inclined to the housing to increase the centrifugal force is weakened, so that the noise emitted to the outside is significantly reduced.

In addition, the size of the hole 62 provided in the porous member 60 is preferably various. That is, as shown in FIG. 3, the size of the through hole 62 of the plate is different from each other, or as shown in FIG. This is because the frequencies of the air passing through the second cyclone chamber 41 can be prevented from overlapping and amplifying.

Furthermore, when the material of the porous member 60 is a sound absorbing material, an excellent noise reduction effect can be obtained.

Next will be described the operation of the cyclone cleaner according to the present invention configured as described above.

The dust and foreign matter that fall on the floor of the room by the operation of the blower unit 4 together with the air through the air inlet 5a of the suction unit 5 and the air inlet 11 of the cyclone separator 10. 22 is sent to the first cyclone unit 30 installed.

The air introduced into the first cyclone unit 30 is pivoted downward between the outer circumferential surface of the first cyclone chamber 31 and the inner circumferential surface of the inner container 22 to separate dust and foreign matter and thus to the first collecting part 32. Will fall. In addition, the air filtered by the dust and foreign matter is continuously introduced into the through hole 33 of the first cyclone chamber 31 to move upward and pass through the first cyclone chamber 31.

Air passing through the first cyclone chamber 31 is spirally moved along the plurality of guide members 52 provided in the upper cap 50 to the plurality of second cyclone chambers 41 provided in the second cyclone unit 40. After being introduced, the container is pivoted downward along the inner circumferential surface of each second cyclone chamber 41.

Due to the air turning in the second cyclone chamber 41, fine dust and foreign matter not filtered out of the first cyclone unit 30 are again filtered to fall to the second collecting part 42, and the filtered air is again filtered. It moves upward along the central axis of the 2-cyclone chamber 41 and passes through the outlet 43.

After passing through the outlet 43 of the second cyclone chamber 41, the air continuously exits the air outlet 12 provided in the upper portion of the upper cap 50, and then moves downward along the discharge guide tube 13. Finally it is discharged to the outside through the blower (4).

5 is a graph showing the effect of the porous member 60 provided in the cyclone cleaner of the present invention, the cyclone cleaner generates a noise of approximately 6 ~ 12dB during operation, the porous member (2) in the second cyclone unit 40 60) will reduce the noise of about 7dB as shown.

As described in detail above, the cyclone cleaner according to the present invention can separate the dust and foreign matter over a second, and can easily empty the separated dust and foreign matter, in particular, each of the second cyclone chamber and the dust collector is formed The porous member is installed in the space to prevent the echo phenomenon caused by the air colliding directly to the dust collector, and also reduces the flow rate of the air to significantly reduce the noise caused by the secondary flow generated from the dust collector. Can be reduced.

In addition, since the porous member is formed with holes of various sizes, even if air passes through a plurality of cyclone chambers having the same shape and size, noise increase due to sound overlap does not occur, so the overall performance and convenience of the cyclone cleaner There is an effect to increase.

Claims (5)

A housing including an outer container and an inner container, a first cyclone unit installed in the inner container to filter dust and foreign matter contained in the intake air, and a first cyclone unit installed in the outer container In the cyclone cleaner including a second cyclone unit for secondary filtering the fine dust and the like contained in the rough air, The second cyclone unit is composed of a plurality of cyclone chamber and dust collection unit, Cyclone cleaner, characterized in that the porous member is provided between the dust collector and the cyclone chamber. The method of claim 1, The porous member is a cyclone cleaner, characterized in that consisting of a plate formed with a plurality of through holes. The method of claim 1, The porous member is a cyclone cleaner, characterized in that consisting of a plate formed with a plurality of lattice holes. The method according to claim 2 or 3, Cyclone cleaner, characterized in that the size of the holes provided in the plate are different. The method of claim 1, The porous member is a cyclone cleaner, characterized in that made of a sound absorbing material.

Images