KR20010001210A - device for revolution of air in cyclone dust collector - Google Patents

Abstract

The present invention relates to a swirl flow generating device of a cyclone dust collector which separates air and dust by using centrifugal force, and increases the swirl force of the air in the process of inhaling the air into the cyclone body to smoothly separate the dust from the air. In addition, it is possible to prevent inhalation caused by the inflow of large foreign matters.

To this end, the present invention is a cyclone body 10, the suction passage pipe 20 is provided integrally to the cyclone body is sucked air and contaminants, and the air sucked into the cyclone body of the cyclone body An air discharge pipe 30 discharged to the outside, and a contaminant discharge hole 40 formed at an opposite side of the side where the suction flow path tube of the cyclone body is located to discharge the contaminants introduced into the cyclone body together with the air; Dust collection cylinder 50 for collecting pollutants discharged through the pollutant discharge hole in a state in communication with the pollutant discharge hole, and a swirl flow generation is provided on the air inlet side of the cyclone body to turn the air sucked into the cyclone body In the cyclone dust collector provided with the means, the spiral flow generating means is constituted by the spiral blade 600, and the air sucked into the cyclone body is spiral-bladed. In a single swirling flow generated in the cyclone collector, it characterized in that the rotary force to be caused, while passing only the flow path 620, an apparatus is provided which is formed by.

Description

Swirl flow generator of cyclone dust collector {device for revolution of air in cyclone dust collector}

The present invention relates to a cyclone dust collector capable of collecting various contaminants such as dust by using the cyclone principle, and more particularly, a swirling flow of inflowed air to facilitate separation of air and contaminants. It relates to a device for generating a.

In general, the cyclone dust collector is a pollutant (dust) that rotates with the air using a centrifugal force to discharge the air to the outside and collect only the pollutant from the air, it is mainly applied to a vacuum cleaner for home use.

The cyclone dust collector has various forms, but the inflow side of the air and the outflow side of the air are formed in the forward direction to separate the air and dust, and the inflow side of the air and the outflow side of the air are reversed (or, It can also be classified into a type that separates air and dust while being formed in a tangential direction.

US Patent Nos. 3870486, 4853008, 4373228, 4643738, 4593429, 5080697, 513552, 5160356 and the like disclose a cyclone apparatus of a vacuum cleaner in which the air flow is reversed. have.

The swirl flow generating portion in these cyclone devices discloses that the swirl force is obtained by allowing air to flow in the tangential direction to the cyclone.

In addition, U.S. Patent No. 537554 discloses that the cyclone device has a helical protrusion formed on a cone part, but this is to allow particles such as dust obtained by turning force to fall smoothly. Like the above, it can be seen that the air is caused to flow in the tangential direction.

EP 815788 discloses a helical air suction tube to obtain turning force.

However, such a tangential inflow or helical air suction tube to generate the turning force in employing the cyclone in the vacuum cleaner, in particular in applying the cyclone to the extension pipe connecting the suction nozzle and the main body of the vacuum cleaner The configuration is not easy, there is a problem that the overall configuration becomes large.

The above problem can be solved by allowing the air flow to be made in the forward direction, and US Patent No. 5350432 discloses a configuration in which such a forward cyclone is employed in the extension tube of the cleaner.

A detailed description thereof will be given with reference to FIG. 1, which is illustrated below.

First, a suction flow path tube 20 through which air and contaminants (dust, lint, pieces of paper, etc.) are sucked is provided on one side of the cyclone body 10 forming a cylindrical shape as a whole, and the suction flow path tube is formed. An opposite side of the clone body 10 is provided with an air discharge pipe 30 through which air introduced into the cyclone body is discharged.

At this time, the air discharge pipe is connected to a suction force generating means (not shown) for generating a suction force so that contaminants can be sucked through the suction flow path tube 20, which is generally the suction force of the fan according to the driving of the motor. As a means for generating a suction force by using the illustration and detailed description thereof will be omitted.

The pollutant discharge hole 40 is discharged to the air discharge pipe 30 of the cyclone body (typically, one side outer side of the cyclone body) to discharge the pollutants introduced into the cyclone body 10 together with the air. It is formed, and the dust collector 50 is provided to collect the pollutants discharged through the pollutant discharge hole in a state in communication with the pollutant discharge hole.

The operation of the cyclone dust collector configured as described above will be described later.

First, when suction force is generated through one side of the cyclone body 10, that is, the air discharge pipe 30, air containing dust is sucked through the suction flow path tube 20 of the cyclone body, and then of the cyclone body. By the swirl flow generating means 60, it pivots along the inner circumferential side.

Accordingly, dust is discharged to the dust collecting container 50 through the pollutant discharge hole 40 on the inner wall of the cyclone body 10, and the air is the cyclone body through the air discharge pipe 30 in which suction force is generated. It is discharged to the outside of the (10).

The dust may be discharged through the pollutant discharge hole 40 on the inner wall of the cyclone body 10 because it has a certain mass.

That is, F = me Air close to zero due to (F; centrifugal force, m; mass, e; distance from the center of the cyclone body to the inner wall of the cyclone body, ω; angular acceleration) produces almost no centrifugal force, Is to rotate the inner wall of the cyclone body under the influence of the centrifugal force.

On the other hand, in the process of introducing the air through the suction flow pipe 20 in the above it is necessary to smoothly separate the dust and air as described above to generate a turning force to the air.

Accordingly, in the related art, the swirl flow generating means 60 having the axial blade 61 is mounted inside the cyclone body to impart a turning force to the air flowing into the cyclone body.

That is, the swirl flow using the swirl flow generating means 60 attached in the radial direction of the shaft 63 in a state in which a plurality of blades 61 maintain a proper space 62, such as a blade of a fan. Air passing through the generating means is to have a turning force by the plurality of blades (61).

However, the conventional swirl flow generating means as described above is simply configured so that the flow path is guided according to the shape of each blade during the passage through the space formed between each wing, so that the turning force was not very good. .

Accordingly, the centrifugal force to be generated in the process of passing the air is relatively weakly generated, and this is because the separation between the dust and air is not made smoothly, there is a problem that the dust collecting force is deteriorated.

In general, the suction flow path tube is formed at the center of one side of the cyclone body, and the air sucked into the center side of the cyclone body through the suction flow path tube passes through the space between the respective wings constituting the swirl flow generating means. This is because in the process of diffusion into the periphery inside the cyclone and the flow is separated into a plurality by the space between each wing.

That is, in the axial flow blade as the swirl flow generating means, each blade is formed in parallel with the air flow direction, and the air flow is divided into a plurality to impart a pivot force while flowing along the curved surface of each blade.

At this time, the turning section in which particles such as dust contained in the air are turned is determined by the length of each blade, and the turning section is small so that the particles do not obtain a large turning force.

Therefore, the air flowing through the suction flow path tube is diffused to the entire cross-sectional area of the cyclone dust collector, and each particle of air passes through the swirl flow generating means from the inner circumferential surface side of the cyclone to the center side, At this time, the particles on the center side are not able to generate more turning force because their turning radius is small.

In addition, by using the axial blades composed of a plurality of wings as the swirl flow generating means, since the suction force acts uniformly over the cross-sectional area of the cyclone dust collector, it is light but bulky such as tissue paper, papers, stockings, and the like. When the large particles pass through the swirl flow generating means, they are attracted by the entire area, and are caught between the respective blades forming the axial blades, thereby blocking the vacuum cleaner suction flow path and causing a definite operational defect. .

As a result, not only the inhalation can be caused, but also the internal pressure is rapidly increased, which causes a problem of damaging the cyclone dust collector.

The present invention has been made in order to solve the above-mentioned conventional problems, to increase the rotational force of the air in the process of inhaling the air into the cyclone body to facilitate the separation of dust and the inflow of large foreign matters The purpose is to be able to prevent the inhalation caused by inhalation.

Figure 1 is a longitudinal cross-sectional view showing a typical forward cyclone dust collector

Figure 2 is a perspective view showing the swirl flow generating means of the general forward cyclone dust collector

3 is a longitudinal sectional view showing a first embodiment of a forward cyclone dust collector equipped with a swirl flow generating means of the present invention;

4 is a perspective view showing the swirl flow generating means of FIG.

Fig. 5 is a longitudinal sectional view showing the second embodiment of the forward cyclone dust collector equipped with the swirl flow generating means of the present invention.

6 is a cross-sectional view taken along line II of FIG. 5.

7 is a longitudinal sectional view showing a third embodiment of the forward cyclone dust collector equipped with the swirl flow generating means of the present invention;

Explanation of symbols for main parts of the drawings

200.Suction channel 201.Air outlet side

600. Spiral Blade 610. Wings

620. Euro 630. Axis

700. Euro guide

According to an aspect of the present invention for achieving the above object, the cyclone body, the suction passage pipe is provided integrally to the cyclone body to suck air and contaminants, and the air sucked into the cyclone body The air discharge pipe discharged to the outside of the body, and the contaminant discharge hole formed on the opposite side of the side of the suction flow path tube of the cyclone body is discharged to the contaminants introduced into the cyclone body with the air, and communicating with the pollution discharge hole Cyclone dust collecting device having a dust collecting container for collecting contaminants discharged through the contaminant discharge hole in a closed state, and a swirl flow generating means for turning the air sucked into the cyclone body in the air inlet side of the cyclone body; In the spiral flow generating means is composed of a spiral blade air drawn into the cyclone body There is provided a swirl flow generating device of a cyclone dust collector, characterized in that the swing force can be generated while passing through only one flow path formed by the spiral blade.

Hereinafter, with reference to the accompanying Figures 3 to 7 showing an embodiment of the present invention in more detail as follows.

3 is a longitudinal sectional view showing the first embodiment of the forward cyclone dust collector equipped with the swirl flow generating means of the present invention, Figure 4 is a perspective view showing the swirl flow generating means of Figure 3, Figure 5 FIG. 6 is a longitudinal sectional view showing a second embodiment of the forward cyclone dust collector equipped with the swirl flow generating means of the present invention, FIG. 6 is a sectional view taken along the line I-I of FIG. 5, and FIG. As the longitudinal cross-sectional view showing the third embodiment of the forward cyclone dust collector, the present invention is constituted by the spiral blade 600 as a means for imparting a turning force to the air sucked in the cyclone body 10.

In other words, unlike the conventional spiral flow generating means (60) having a plurality of axial blades (wings) 61, the external blades are sucked into the cyclone body in a state in which a plurality of air flow paths are separated. By using 600, the air flow path is composed of only one, so that the turning section is sufficiently secured without increasing the swirl flow generating means.

At this time, the spiral blade has a shaft 630 in the center, by forming a blade 610 along the circumference of the shaft to form a flow path 620 to guide the air along the formed flow path. .

In addition, instead of the configuration having a shaft 630 in the center of the spiral blade 600 as described above, a spiral guide guide (not shown) along the inner wall of the cyclone body 10 so that air can be rotated spirally. It can be installed.

If described in more detail the operation according to the first embodiment of the present invention configured as follows.

First, when the suction force generating means (not shown) according to the user's needs, the suction force is generated through one side of the cyclone body 10, that is, through the air discharge pipe 30.

Therefore, the air containing the dust is sucked through the suction flow path tube 200 of the cyclone body 10 by the suction force.

As such, the air sucked into the cyclone body 10 generates a turning force in the process of flowing along the wing 610 of the spiral blade 600 provided in the cyclone body, and the spiraling force as described above. Air passing through the blade is discharged through the air discharge pipe 30 provided on one side of the cyclone body while turning along the inner circumference of the cyclone body (10).

At this time, a large amount of dust is contained in the air turning in the cyclone body, and the dust is subjected to centrifugal force as it has a constant mass.

Accordingly, the dust is discharged to the dust collecting container 50 through the pollutant discharge hole 40 while being separated from the air while turning around the inner wall of the cyclone body 10.

Meanwhile, in the present invention, the air outlet side 201 of the suction flow path tube 200 faces the start end 611 of the blade 610 constituting the spiral blade 600 so as to make the turning force of the sucked air more excellent. Most preferably.

FIG. 5 shows a second embodiment of the dust collecting apparatus employing the spiral blade of the present invention as the swirl flow generating means. The suction flow path 200 is partially eccentrically formed from the center of the cyclone body 10. The direction in which the suction flow path is directed is possible by being located on the same line as the start end 611 of the blade 610 constituting the spiral blade 600.

In addition, FIG. 7 shows a third embodiment different from the second embodiment in order to increase the turning force of the air to be sucked, and when the suction flow path 200 is not eccentric as in the second embodiment It may be provided with a flow path guide guide 700 toward the start end 611 side of the wing 610 constituting the air outlet side 201 and the spiral blade 600 of the suction flow pipe.

That is, the air sucked through the suction flow pipe 200 may be guided to the start end 611 of the spiral blade 600 by the flow path guide guide 700 so that the suction air can exert the maximum turning force. .

FIG. 6 shows a preferred position of the suction flow path tube when configured as in the second and third embodiments, and the air outlet side 201 of the suction flow path tube is the start end 611 of the spiral blade 600. It is preferable to install so as to be partially biased into the flow path 620 of the spiral blade with respect to the position.

That is, when the position of the start end 611 of each blade 610 in which the air flow of the spiral blade 600 starts and the center of the air outlet side 201 of the suction flow path 200 coincide with the suction flow path tube Part of the air (half) sucked through can be smoothly introduced into the spiral blade, but the other part (half) is turned from a certain circumferential length of the turning section consisting of the spiral blade, so the turning force of the spiral blade The efficiency will not be maximized.

As described above, the present invention can obtain the following effects by improving the air intake flow path structure in the cyclone body constituting the cyclone dust collector.

First, in the process of inhaling the air into the cyclone body, the flow is not dispersed in plural, but concentrated in one, so that the suction force is concentrated, thereby increasing the turning force of the air.

Accordingly, separation of air and dust contained in the air can be performed more smoothly.

Second, even if large foreign matters can be smoothly discharged to the dust collector in the cyclone body.

Accordingly, clogging of the flow path by the large foreign matter is prevented, there is an effect that can prevent problems such as inhalation inability.

Third, even if the size (diameter or length) of the swirl flow generating means is not increased, a sufficient swing section can be secured, and the swing force can be greatly improved.

Claims (5)

A cyclone body, an intake passage tube integrally provided in the cyclone body to suck air and contaminants, an air discharge pipe through which air sucked into the cyclone body is discharged to the outside of the cyclone body, and the cyclone It is formed on the opposite side of the body side of the suction flow path is located, the pollutant discharge hole to discharge the pollutant introduced into the cyclone body with the air, and collects the pollutant discharged through the pollutant discharge hole in communication with the pollutant discharge hole In the cyclone dust collector, the cyclone dust collecting device is provided with a swirl flow generating means for pivoting the air sucked into the cyclone body is provided on the air inlet side of the cyclone body, The swirl flow generating device of the cyclone dust collecting device, characterized in that the swirl flow generating means is composed of a spiral blade so that the air sucked into the cyclone body can pass through only one flow path formed by the spiral blade to generate the swirl force. . The method of claim 1, A swirl flow generating device of a cyclone dust collector, characterized in that the air outlet side of the suction flow path is formed to face the start end side of the spiral blade. The method of claim 2, A swirl flow generating device of a cyclone dust collector, characterized in that the air outlet side of the suction flow path tube is formed eccentrically from the center of the cyclone body so as to face the start end side of the spiral blade. The method of claim 2, A guide guide is provided in the cyclone body from the air outlet side of the suction flow path to the start end side of the spiral blade so that air introduced through the suction flow path is guided to the start end of the spiral blade by the guide guide. Swirl flow generating device of the cyclone dust collector. The method according to any one of claims 3 to 4, And the air outlet side of the suction flow path tube is biased toward the inside of the flow path of the spiral blade with respect to the start end position of the spiral blade.