KR20030094861A - cyclone type vacuum cleaner - Google Patents

Abstract

PURPOSE: A cyclone vacuum cleaner is provided to reduce noise and pressure loss, and to prevent dust from scattering by improving the structure and mounting structure of a cyclone dust collector. CONSTITUTION: A cyclone vacuum cleaner is composed of a cleaner body(200), a cyclone dust collector installed in the cleaner body, and a dust chamber(300) collecting dust separated by the cyclone dust collector. The cyclone dust collector includes a cyclone body(110) connected to a suction tube(120), a dust separating unit(130) separating dust from sucked air, and a suction generating unit(150).

Description

Cyclone vacuum cleaner

The present invention relates to a vacuum cleaner having a cyclone dust collector capable of collecting contaminants using the cyclone principle.

In general, the cyclone vacuum cleaner uses the cyclone principle to discharge air from the pollutants that rotate with the air to the outside and collect only the pollutants by separating them from the air.

FIG. 1 is a schematic longitudinal cross-sectional view showing an example of a conventional cyclone dust collector installed in the above vacuum cleaner, and FIG. 2 is a cross-sectional view taken along line II of FIG.

As can be seen from this, the conventional cyclone dust collector has a cyclone body 10 formed in a conical shape, a suction flow path tube 20 connected to a flow path through which the air of the vacuum cleaner is sucked, and the air introduced into the cyclone body. It is largely composed of a discharge passage pipe 30, which is discharged, and a dust collecting container 40 in which dust is collected in the cyclone body.

At this time, the suction flow path tube 20 is connected to the upper end of the circumferential surface of the cyclone body (10).

In addition, the discharge passage pipe 30 is connected to the penetrating state so as to penetrate the upper surface of the cyclone body 10 to reach the inner upper end of the cyclone body 10.

In addition, the other end of the discharge passage pipe 30 is connected to the suction force generating means 50 for transmitting the air suction force.

At this time, the suction force generating means 50 is a means for generating the suction force by the rotation of the fan 52 in accordance with the driving of the motor 51, the detailed illustration and detailed description thereof will be omitted.

In addition, the dust collecting container 40 is provided to communicate with the pollutant discharge hole 11 formed on the bottom surface of the cyclone body 10.

Referring to the operation of the conventional cyclone dust collector made of the above-described configuration is as follows.

First, when the operation of the vacuum cleaner is selected to drive the suction force generating means 50, suction of external air containing contaminants is performed through the suction flow path 20 into the cyclone body 10.

At this time, the air containing the contaminant is sucked in a tangential direction with respect to the cyclone body 10 through the suction flow path tube 20 of the cyclone body 10, the inside of the cyclone body 10 Descend by turning along the wall.

In this process, air and contaminants are separated from each other under different centrifugal forces due to their weight differences.

That is, the relatively heavy contaminants flow down the inner wall surface of the cyclone body 10 while being subjected to centrifugal force to be discharged to the dust collector 40 through the contaminant discharge hole 11, and the relatively heavy The small air is discharged out of the cyclone body 10 by the suction force transmitted through the discharge flow path tube 30.

In this case, the air having almost no weight hits the bottom surface of the cyclone body 10 by the suction force generated through the discharge flow path tube 30 to form an upward airflow along the center of the cyclone body 10. While rising to be discharged to the outside of the cyclone body 10 through the discharge flow path (30).

However, the conventional cyclone vacuum cleaner which performs the above-described structure and operation has the following problems.

First, there is a problem of noise generation as the contaminants come into contact with the inner wall surface of the cyclone body while descending while turning along the inner wall surface of the cyclone body.

In particular, there is a problem in that the noise is intensified because the length between the portion where the turning of the contaminant starts and the portion where the pollutant discharge hole is formed is long.

Second, there is a problem that the pollutants having a relatively small weight were discharged through the discharge passage pipe together with the air without turning the inner wall surface of the cyclone body.

In this case, the contaminants discharged through the discharge flow path pipe are introduced into the suction force generating means, causing the damage of the suction force generating means.

Third, as the overall air flow path is made long, the pressure loss is generated to increase the noise, and the damage caused by the load increase of the motor constituting the suction force generating means is caused.

That is, due to the discharge flow pipe formed in the conventional cyclone dust collector, the flow path between the suction force generating means and the cyclone body is long, resulting in a pressure loss.

Fourth, the conventional cyclone dust collector has a space in which the suction force generating means is mounted and a space in which the cyclone body is mounted, respectively, and the spaces are connected to each other by the discharge flow path tube. In addition, there was a space in which the dust collector is mounted.

As such, as the respective mounting spaces are required, the overall size of the vacuum cleaner to which the cyclone dust collecting device is applied increases.

The present invention has been made to solve the above-mentioned conventional problems, to improve the structure of the cyclone dust collector mounted on the vacuum cleaner and the mounting structure of the cyclone dust collector to reduce noise and pressure loss as much as possible In addition, the purpose is to prevent the scattering of contaminants, and to reduce the overall size of the vacuum cleaner.

1 is a schematic longitudinal cross-sectional view showing an example of a cyclone dust collector according to the prior art;

2 is a cross-sectional view taken along line II of FIG. 1.

Figure 3 is a perspective view of the main part cutaway schematically showing the internal structure of the vacuum cleaner to which the present invention cyclone dust collector is applied

Figure 4 is a cross-sectional view showing the internal structure according to the vacuum cleaner to which the present invention cyclone dust collector is applied

5 is a cross-sectional view taken along the line II-II of FIG. 4.

Explanation of symbols for main parts of the drawings

110. Cyclone body 120. Suction channel

130. Contaminant separator 200. Vacuum cleaner body

300. Dust Collector

According to the present invention to achieve the above object, a cleaner body; A cyclone dust collector provided in the cleaner body in a state in which contaminants are separated and a space in which suction force is generated are directly connected to each other; And, a vacuum cleaner is provided, characterized in that it comprises a dust collector: for collecting the contaminants separated through the cyclone dust collector.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to FIGS. 3 to 5.

3 to 5 schematically show a vacuum cleaner according to the present invention.

That is, the vacuum cleaner according to the present invention is a cyclone dust collecting device and a cyclone dust collecting device configured to be directly connected to the cleaner body 200, a portion that is installed in the vacuum cleaner body, and generates a suction force and a portion separating the contaminants directly, It comprises a dust collector (300) installed in the same direction as the dust collector.

The cleaner body 200 is connected to a suction hose 210 for receiving various contaminants sucked from the suction sphere (not shown), and the wheels 220 for movement thereof are respectively mounted.

In addition, the cyclone dust collecting device constituting the vacuum cleaner of the present invention is proposed to include a cyclone body 110, a contaminant separating unit 130, and a suction force generating means 150.

At this time, the cyclone body 110 is provided in the upper portion of the cleaner body, the height is the same as the width (diameter) of the cyclone body 110, or is formed in a low cylindrical shape, the outside air is sucked in In addition to being connected to the suction flow path pipe 120 is a contaminant discharge hole 111 is formed is discharged contaminants are formed.

In the suction passage pipe 120 is connected along the tangential direction of the circumferential surface on the circumferential surface of the cyclone body 110, the pollutant discharge hole 111 is one side of the circumferential surface of the cyclone body 110 It is formed by incision.

At this time, the portion of the pollutant discharge hole 111 is inserted into the interior of the dust collecting container 300 through the coupling hole 310 formed on one side of the upper end of the dust collecting container 300, the suction flow path tube ( The other end of the 120 is connected to the suction hose 210 provided in the cleaner body 200.

Its configuration can achieve noise reduction and load reduction by eliminating the flow path between the dust collector and the cyclone body. Along with this, the cyclone body 110 and the dust collecting container 300 can be attached and detached so that the pollutants collected in the dust collecting container can be discharged smoothly.

In addition, the contaminant separating unit 130 is provided inside the cyclone body and is configured to have a predetermined space between the circumferential surface of the cyclone body 110 and the contaminant separating unit 130, and has a predetermined inner diameter. It is formed of a cylindrical filter body having a hollow state.

In addition, the axial direction of the contaminant separating unit 130 is installed to form the same direction as the axial direction of the cyclone body 110, and the inside of the hollow state is positioned to communicate with the suction force generating means 150.

That is, the space forming the inner portion of the pollutant separator 130 serves as a discharge flow path tube through which air is discharged.

In particular, the height of the pollutant separation unit 130 is formed to be the same as the height of the cyclone body 110 to minimize the occurrence of turbulence that may occur inside the cyclone body (110).

In addition, the suction force generating means 150 is provided on the lower space in the cleaner body, the housing 151 directly connected to the contaminant separating unit 130, the blowing fan 152 and the blowing fan mounted in the housing It is configured to include a drive motor 153 for driving.

At this time, the housing 151 and the contaminant separating unit 130 are coupled to each other so that the sealing is made except for the portions communicating with each other.

It can be seen that the cyclone dust collector having the configuration as described above is installed vertically with respect to the cleaner body 200.

That is, the suction force generating means 150 is installed on the lower space in the cleaner body 200 when the inside of the cleaner body 200 is viewed from the side as shown in FIG. 4, and the cypress is disposed on the upper space in the cleaner body 200. The clone body 110 and the contaminant separation unit 130 are installed to form a mutually installed longitudinal direction.

In addition, the dust collecting container 300 constituting the vacuum cleaner of the present invention is formed in a state of standing in the same gravity direction as the direction in which the suction force generating means 150 and the contaminant separating unit (or the cyclone body) 130 are coupled. do.

As a result, the overall construction area can be reduced as much as possible and the maximum dust collection volume can be obtained.

At this time, the upper surface of the dust collecting container 300 is configured to selectively open and close to facilitate the discharge of the collected dust.

In addition, the dust collecting cylinder 300 as described above may be formed into a cylinder having various shapes such as a cylinder, a rectangular parallelepiped, or a polyhedron, and thus the limitation to a specific form is omitted.

As described above, the cyclone vacuum cleaner of the present invention can not only reduce the overall size by directly configuring the cyclone dust collector, but also reduce the load and noise by greatly reducing the flow path of the air by vertically configuring it. It can be achieved.

In particular, according to the above-described configuration of the present invention, a large amount of free space is formed on the side portion of the cleaner body 200 as compared to a conventional cyclone vacuum cleaner, and the free space is selectively taken out of other components such as a power cord. By mounting a cord reel (not shown) for mounting or the like, the existing mounting space for the component can be reduced, thereby reducing the width and height of the overall vacuum cleaner.

Hereinafter, the operation of the vacuum cleaner of the present invention will be described with reference to a cleaning process using the vacuum cleaner of the present invention configured as described above.

First, when the operation of the vacuum cleaner is selected and the suction force generating means 150 is driven, the suction force generated according to the driving passes through the cyclone dust collector to connect the suction hose 210 connected to the cleaner body 200. Through the air is sucked out of the cleaner.

Accordingly, the cyclone body 110 is made of suction of external air through the suction passage pipe 120.

At this time, the outside air sucked as described above contains a predetermined contaminant.

However, the air containing the contaminant as described above is introduced into the cyclone body 110 through the suction flow path pipe 120 of the cyclone body 110 is subjected to the centrifugal force in the process of turning and separated from each other Is done.

In addition, the contaminants and the air may be separated from each other because there is a difference in weight between the air and the contaminants, and in particular, the suction flow path pipe 120 is connected to the cyclone body 110 in a tangential direction and thus a greater centrifugal force By applying this, more smooth separation is achieved.

That is, the relatively heavy pollutants are discharged to the dust collector 300 through the pollutant discharge hole 111 while turning on the inner wall surface of the cyclone body 110 by applying centrifugal force, and the air having a relatively small weight. Is passed through the contamination separation unit 130 is discharged to the space where the suction force generating means 150 is located.

In the above process, the fine dust having an extremely small weight may be discharged through the contaminant separating unit 130 with air without being strongly subjected to the centrifugal force.

However, as the pollutant separator 130 is formed of a hollow cylindrical filter body, fine dust is caught from the air by the pollutant separator 130 and remains in the cyclone body 110.

Only clean air is discharged into the space where the suction force generating means 150 is located, thereby preventing damage to the suction force generating means 150 due to contaminants.

In particular, since the suction force generating unit 150 is directly connected to the contaminant separating unit 130, there are no flow paths therebetween. Accordingly, the occurrence of pressure loss and noise due to the flow path are prevented as much as possible.

In addition, the fine dust that is forcibly separated from the air by the contaminant and the contaminant separating unit 130 that has not been discharged through the contaminant discharge hole 111 among the contaminants turning on the inner wall surface of the cyclone body 110 in the above process. Is rotated again along the inner wall surface of the cyclone body 110 is discharged to the dust collecting container 300 through the pollutant discharge hole 111.

If contaminants and fine dust remain in the space between the cyclone body 110 and the contaminant separating unit 130 by the above-described process, after the cleaning is completed, the contaminants are discharged.

This is possible because the dust collecting container 300 is detachably coupled to the cyclone body 110 and the contaminant separating unit 130 and the suction force generating unit 150 are detachable from each other.

Of course, one side of the cyclone body 110 (the side that is not coupled with the suction input generating means) may be configured to be opened and closed to enable the smooth discharge of the contaminants and the cleaning of the contaminant separator 130.

As described above, according to the cyclone vacuum cleaner according to the structure of the present invention, the following effects can be obtained.

First, by applying a cyclone dust collector reduced in size, the height, length, or width of the vacuum cleaner can be significantly reduced.

Second, by improving the structure of the cyclone dust collector, the contact time between the pollutant and the cyclone body is reduced as much as possible, thereby reducing the noise due to friction between them.

Third, it is possible to reduce the pressure loss as much as possible by forming the air flow path as short as possible, thereby reducing the noise and load reduction of the motor constituting the suction force generating means.

Fourth, there is an effect to prevent the problem that the contaminant having a relatively small weight, such as dust is discharged to the suction force generating means by configuring the contaminant separator using the filter body.

Claims (9)

A cleaner body; A cyclone dust collector provided in the cleaner body in a state in which contaminants are separated and a space in which suction force is generated are directly connected to each other; And, Dust collector for collecting the contaminants separated through the cyclone dust collector: comprising a vacuum cleaner. The method of claim 1, The cyclone dust collector is A cyclone body connected to a suction flow pipe through which external air is sucked; A contaminant separating unit provided in the cyclone body and separating contaminants from the air sucked through the suction flow pipe; And, And a suction force generating means installed to be directly connected to the contaminant separating unit and transmitting an air suction force. The method of claim 2, The cyclone body and the contaminant separator that constitute the cyclone dust collector and the suction force generating means Vacuum cleaner, characterized in that installed in the vertical with respect to the cleaner body. The method of claim 3, wherein The cyclone body of the cyclone dust collector installed vertically And a contaminant discharge hole communicating with a dust collecting container, and a portion where the contaminant discharge hole is formed is inserted into and coupled to the inside of the dust collecting container. The method of claim 4, wherein Pollutant discharge hole Cyclone dust collecting device, characterized in that formed by cutting one side of the peripheral surface of the cyclone body. The method of claim 2, Contaminant Separation And a cylindrical filter body in a hollow state, the axial direction of which is in the same direction as the axial direction of the cyclone body, and wherein the hollow interior is positioned to communicate with the suction force generating means. The method of claim 6, The cyclone dust collecting device, characterized in that the height of the dirt separation unit is formed equal to the height of the cyclone body. The method of claim 2, Suction force generating means A housing installed to be directly connected to the contaminant separating unit, And a blower fan mounted in the housing and a drive motor for driving the blower fan. The method of claim 2, Cyclone dust collecting device, characterized in that the contaminant separating portion and the suction force generating means is configured to be detachable.