NL1024302C2 - Cyclone type dust collecting device for vacuum cleaner. - Google Patents

Description

i

Cyclone type dust collecting device for vacuum cleaner.

BACKGROUND OF THE INVENTION

1. Field of the invention.

The present invention relates to a vacuum cleaner, and more particularly to a cyclone-type dust collecting device of a vacuum cleaner for separating and collecting dust and contaminants from air loaded with contaminants, by means of a centrifugal force that is generated by the generation of an air swirl.

10 2. Background of the relevant technique.

FIG. 1 and 2 are views of examples schematically showing a cyclone-type dust collecting device for a vacuum cleaner.

With reference to FIG. 1 and 2, reference numeral 100 denotes the cyclone type dust collecting device, 200 denotes a vacuum cleaner housing, and 300 denotes a cleaning brush (not shown in Figure 1). The dust collecting device of the cyclone type 100 is provided with a cyclone body 10, the dust collecting device 20 and a grid 30.

As shown in FIG. 1 and 2, the cyclone body is provided with an air inlet tube 11 and an air outlet tube 12. The air inlet tube 11 is connected to an air inlet (not shown) on one side of the cyclone body 10. The air inlet tube 11 is connected to an air inlet path 210 which is designed to be in fluid communication with a suction nozzle (not shown) of the suction brush 300 when the cyclone-type dust collecting device is installed in the vacuum cleaner housing 200. The air outlet tube 12 is connected to an air outlet (not shown) at the top 30 side of the cyclone body 10. The air outlet tube 12 is connected to an air outlet path 220 designed to be in fluid communication with a motor drive chamber 310 of the suction brush 300 when the cyclone-type dust collecting device is installed in the dust container. No. 1024302 I piston housing 200. The air laden with dirt is sucked in through the suction brush 300 into the cyclone body I 10 in a tangential direction through the air inlet path 210 I of the vacuum cleaner housing 200 and air inlet tube 11. The air that is sucked in forms a swirling air stream in the cyclone body 10 and in this way the dust and dirt are separated from the dirt-laden air by a centrifugal force of the air vortex through which the clean air is ejected out via the air outflow path 220 of the vacuum cleaner housing 200 and the engine room 310.

The dust collector 20 is removably connected to the bottom of the cyclone body 10 and receives the dust and dirt separated from the air by a centrifugal force of the swirling air stream in the cyclone body 10.

The grid 30 is arranged at an opening of the air outflow tube 12 within the cyclone body 10 to prevent dust and dirt separated from the swirling air from flowing through the air outflow tube 12. As shown in Figure 2, a grille 30 includes a grille body 31 and a plurality of air paths 32 arranged on an outer circumference of the grille body 31, allowing air to flow to the air outlet. flow tube 12.

The general cyclone-type dust collecting device, as described above, is installed in the dust-piston housing 200 so that the air inlet tube 11 and the air outlet tube 12 of the cyclone body 10 are connected to the air inlet path 210 and the air inlet path 210, respectively. I air outlet path 220 of the vacuum cleaner body 200.

During operation, a suction force is generated at the suction brush 300 by a motor in the motor chamber 310.

The generated suction sucks the dirt-laden air from a surface to be cleaned in the cyclone body 10 through the suction brush 300, air inlet path 210 and air inlet tube 11. The air sucked in is passed through the air inlet tube. guided along the inner circumference of the cyclone body 10 in an oblique direction to form a swirling air stream. Dust and dirt in the air are separated by a centrifugal force that is generated by the swirling air stream and are collected in the dust collector 20. The clean air is ejected out through the air paths 32, air outflow tube 12, air outflow path 220 and engine room 310.

However, the general cyclone-type dust collecting device as described above has a problem of reducing cleaning efficiency. Related cyclone-type dust collecting devices failed to hold a sufficient amount of dust and allowed dust and contamination to be ejected with the outflow of air through the air path 32 in the grid 30.

SUMMARY OF THE INVENTION

An object of the present invention is to at least eliminate the above problems and / or disadvantages and to provide at least the advantages described below.

Therefore, it is an object of the present invention to solve the foregoing problems by providing a cyclone-type dust collecting device for a vacuum cleaner capable of maximizing the separation of clean air from contaminated air by controlling a grid. run that helps prevent dust from escaping from a dust collection device.

The foregoing and other objects and advantages are achieved by providing a cyclone-type dust-collecting device for a vacuum cleaner comprising: a cyclone body with an air inlet and an air outlet, for forming a swirling air stream of air loaded with dirt that is sucked in through the air inlet; a dust collector removably connected to a cyclone body to collect dust and dirt separated by the air by a centrifugal force of the swirling air stream in the cyclone body; a grid arranged on the air outlet I within the cyclone body to prevent dust and dirt separated from the air from flowing through the air outlet I; and means for supporting grid rotation that supports the grid rotating through the swirling air in the cyclone body.

The cyclone body is provided with: a cylindrical main body provided with a side surface on which the air inlet is arranged and an upper surface on which the air outlet is arranged; and a cover removably connected to the upper surface of the cylindrical main body, wherein an air inlet tube connected to an air inlet path of the main vacuum cleaner housing I is arranged in the air inlet and an air outlet tube I which is connected to an air outlet of the vacuum cleaner body is arranged approximately in the center of the cover.

The cylindrical main body and cover are removably connected to each other by spiral-shaped connecting mechanisms which are respectively mounted on the corresponding surfaces of each other for connection.

I The grid is provided with: a grid body; and a plurality of air path components arranged on an outer circumference of the grid body at a predetermined angle of inclination, to form an air passage to the air outlet.

The grid can preferably further be provided with: a blocking part for dirt which is arranged on a lower part of the grid body.

The means for supporting and rotating the grid comprises: a support member, supported to be positioned at the center of the air outlet of the main cylindrical body through a plurality of ribs projecting from an inner surface of the air outlet ; I and a rotating part, one end of which is pivotally supported by the provision of a bearing and the other end is driven by the grating to be screwed onto the lower part of the grating.

According to the cyclone type dust collecting device in accordance with the present invention, a fine dust filter assembly is disposed between the upper surface of the cylindrical main body and the cover for filtering fine dust.

The filter composition for the fine dust is provided with: a filter for fine dust; and a filter frame 10 with a lower part as grid structure, to receive and support the fine dust filter.

Preferably the upper surface of the cylindrical main body is shaped to obliquely slope from the outside to the inside.

Additional advantages, objects, and features of the present invention will be described in part in the description which follows and in part become apparent to those skilled in the art after studying the following or may be learned from the practice of the present invention. The objects and advantages of the present invention can be achieved and achieved as specifically indicated in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS.

The present invention will be described in detail with reference to the following drawings in which the same reference numerals refer to the same parts in which:

FIG. 1 is a perspective view showing a conventional cyclone-type dust collecting device and an associated vacuum cleaner;

FIG. 2 is a sectional view of the cyclone dust collecting device of FIG. 1 after assembly and installation; FIG. 3 is a perspective view of a cyclone-type dust collecting device in accordance with 1024302 I - 6 - I with an embodiment of the present invention before I assembly; FIG. 4 is a cross-sectional view showing the cyclone type dust collecting device of FIG. 3 no composition;

FIG. 5 is a perspective view of the cyclone-type dust collecting device of FIG. 3 before I installing it in a vacuum cleaner.

FIG. 6 is a top cross-sectional view of the cyclone dust collecting device of FIG. 3 I taken along the line 6-6.

FIG. 7 is an enlarged view of an air path I component of the cyclone type I dust collecting device of FIG. 3.

I 15 I DETAILED DESCRIPTION OF THE IMPLEMENTATION

I MEN

As shown in FIG. 3 and 4 is a cyclone-type dust collector for a vacuum cleaner in accordance with an embodiment of the present invention provided with a cyclone body 50, a dust collector 60, a grid 70 and a means for turning and servicing I support the grate 80.

The cyclone body 50 is provided with a cylindrical main body 51 and a cover 52 which is removably connected to the cylindrical main body 51. Cylindrical main body 51 is provided with a side surface 51a and an upper surface 51b. An air inlet is provided on one side of the side surface 51a, and an air outlet I is provided at approximately the center of the upper surface 51b. An air inlet tube 53 is connected to the air inlet, which is also connected to an air inlet path I 210 (see Fig. 5) of a vacuum cleaner housing 200. An air outlet tube 54 is connected to the air outlet at approximately the center of the cover 52 which is also connected to an air outlet path 220 (see Fig. 5) of the main vacuum cleaner housing 200.

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During operation, dirt-laden air is sucked in through a suction brush 300 (see Fig. 5) into the cyclone body 50 in a tangential direction through the air inlet path 210 and air inlet tube 53. In this process, an air swirl is formed in the cyclone body 50, and the dust and dirt contained in the air vortex is separated from the air by the centrifugal force of the air vortex and thus the clean air is ejected out through the air outlet tube 54, the air outlet path 220 and a motor drive chamber 310 (see FIG.

5).

The dust collector 60 is removably connected to a bottom of the cyclone body 50 and receives the dust and dirt separated from the air by the air swirl in the cyclone body 50. The dust collector 60 may be provided with a handle for easy handling possible. When the dust container 60 is full, the dust container 60 can be separated from the cyclone body 50 to empty the dust container 60.

The grille 70 is arranged at the air outlet in the cyclone body 50 to support the separation of dirt and dust that has been separated from the vortex and prevent it from flowing through the air outlet. Grille 70 is provided with a grille body 31 and a plurality of air path parts 72 arranged in an outer circumference of the grille body 71 which forms air passages to the air outlet.

In some embodiments, the means for supporting and rotating the grid 80 is provided with a support member 81 and a swivel member 82. The support member 91 is disposed at a center of the air outlet of the cylindrical main body and is supported by a plurality of ribs 81a protruding from an inner surface of the air outlet. The rotating part 82 is rotatably supported at one end by the provision of a bearing. The other end extends through the grid 70 and is attached to the grid 70 on a lower part of the grid 70 by means of a screw I 84. The grid 70 therefore rotates with the rotating part 82 relative to the supporting part 81 by the whirling air stream formed in the cyclone body 50.

The rotation of the grille 70 helps to prevent the dust and dirt from flowing through the air passage of the grille I 70.

In the cyclone-type dust collecting device 70 of the present invention, the grid 70 can be adapted to include a grid body 71, wherein a plurality of air path parts 72 are arranged in a predetermined angle of inclination to allow an air passage. to the air outlet and a dirt blocking part 73 disposed on the lower part of the grille body 71.

Figures 6 and 7 show in detail the angle of inclination I is preferred and the ratio to the air swirl. Dirt-laden air 302 is sucked in through the air inlet tube 53 in a tangential direction. As discussed above, this causes the formation of a swirling air stream 304 within the main cylindrical body 51. In the embodiment shown in Figure 6, the swirling air stream 304 rotates within the cylindrical main body 51. clockwise.

Preferably, air path components 72 are arranged on the grid body 71 in a manner that minimizes the chance that dust and other dirt will pass through grid 70.

Figure 7 shows an enlarged view of two adjacent air path parts 312 and 314. Air path part 30 314 has a front edge 316 and a rear edge 318. Front edge I 316 is the first edge of the air path part 314 that encounters the swirling air flow 304 . In other words, leading edge 316 is upstream of trailing edge 318.

Preferably, front edge 316 is connected to grid body 71 and rear edge 318 is arranged both radially outside and in the circumferential direction downstream of front edge 316.

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A slope angle 310 is formed with this composition. Slope angle 310 is the angle between a local tangent line 308 and an air path component 314. Local tangent line 308 is a line perpendicular to a radius 306 extending from the geometric center of grid 70 to the air path component 314. Each air path component that has a slope is called sloping. This slope angle 310 can be adjusted for various design objectives. For example, if the slope angle 310 would be reduced, that would increase the ability of grid 70 to separate dirt from the air, but would also increase the power required to suck the air through grid 70. If the angle of inclination 310 is increased, that would reduce the separation efficiency of grid 70, but less power would be needed to suck the air through grid 70. With these different factors as given, an appropriate slope angle can be chosen that best fits certain design objectives.

The rotating property of the grid and the property of the inclined air path can be used independently or in combination with each other.

As best seen in Figure 4, dirt blocking member 73 is in the form of a truncated cone with an enlarged lower member whose diameter increases in the downward direction. This shape may cause dirt collected in the dust collector 60, which floats in the upwardly moving air stream, to be changed direction by the dirt blocking member 73, and thereby fall into the dust collector 60.

The cyclone-type dust collecting device for the vacuum cleaner in accordance with the present invention is further provided with a fine dust filter assembly arranged between the cylindrical main body 51 and cover 52 of the cyclone body 50 to filter the fine dust that is not has been removed by the grid 70.

1o? The fine dust filter assembly 90 is provided with a fine dust filter 91 such as a sponge or other porous material and a filter frame 92 with a lower lattice structure to receive the fine dust filter 91 I 5 and support. The fine dust filter assembly 90 filters the fine dust that has passed through the grid 70 and prevents this fine dust from escaping from the cylindrical main body 51. The upper surface 51b is preferably inclined downwardly from the radial outer circumference to a center portion, so that the fine dust filtered through the fine dust filter assembly 90 falls down to the dust collector 60 instead of remaining between the upper surface 51b of the cylindrical main body 51 and the filter composition for the fine dust 90.

The I cyclone type dust collecting device described above for a vacuum cleaner can be installed in a vacuum cleaner housing 200, as shown in FIG. 5, so that the air inlet tube 53 and the air outlet tube 54 of the cyclone body 50 are respectively connected to the air inlet path 210 and the air outlet path 220 of vacuum cleaner housing 200.

During operation, a suction force generated at the suction brush 300 is driven by a motor (not shown) in motor chamber 310. The generated suction sucks dirt-laden air from a surface to be cleaned in the cyclone body 50 through the suction brush 300 , air inlet path 210 and air inlet tube 53. The air I sucked in is guided through the air inlet tube 53 along an inner circumference of the cyclone body 50 in an oblique direction. This I helps to form a swirling air stream, and the dust I and dirt in the air are separated by a centrifugal force that is generated by the vortex and is collected in the dust collector 60. Then clean air I 35 is expelled emitted through the air passage of grid I 70, air outlet tube 54, air outlet path 220 and through engine chamber 310. With this composition, dust and dirt rarely escape through air outlets of grid 70. However, even when the fine dust, not through the grid 70 is separated, is expelled through the air passage of the grid 70, the fine dust is filtered through the fine dust filter composition 90 (see Fig. 4), thereby improving the amount of collected dust.

According to the present invention described above, dust and dirt are separated from the air by the centrifugal force while the grid rotates to prevent dust and dirt from flowing through the grid, therefore dust and dirt hardly flow through the air passages of the grid.

Furthermore, even when the fine dust flows through the air passage of the grid, the fine dust is filtered through the fine dust filter composition, thereby improving the quality of the dust collection and also the efficiency of cleaning. .

Although the present invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention as defined. by the appended claims.

The embodiments and advantages described above serve primarily as an example and are not to be construed as limiting the present invention. What is described herein can be applied directly to other types of devices. The description of the present invention is intended to be illustrative and not to limit the scope of the claims. Many alternatives, changes and variations will be apparent to 35 experts. In the claims, means-plus-function clauses are intended to encompass the constructions described herein as performing said functions, and include not only constructive equivalents but also equivalent constructs.

Claims (20)

A cyclone-type dust collecting device for a vacuum cleaner comprising: a cyclone body with an air inlet and an air outlet, suitable for forming an air swirl of dirt-laden air that is sucked in through the air inlet; a dust collector removably connected to the cyclone body intended to receive dust and dirt separated from the air by a centrifugal force 10 of the air swirl in the cyclone body; a grid disposed at the air outlet within the cyclone body to prevent dust and dirt separated from the air from flowing through the air outlet; and means for supporting and rotating the grid to support the grid and cause it to rotate through the swirling air stream in the cyclone body. A cyclone type dust collecting device according to claim 1, wherein the cyclone body is provided with: a cylindrical main body with a side surface on which the air inlet is arranged and an upper surface on which the air outlet is arranged; and a cover removably connected to the upper surface of the cylindrical main body, wherein an air inlet tube is arranged for connection to an air inlet path of the vacuum cleaner housing, and an air outlet tube is arranged for connection to an air outlet path of the vacuum cleaner housing, wherein the air outlet and also the tube are arranged approximately at the center of the cover. The cyclone-type dust collecting device according to claim 2, wherein the cylindrical main body and cover are removably connected to each other by spiral connection mechanisms which are respectively mounted on the corresponding surfaces of each other for connection. A cyclone-type dust collecting device according to claim 2, wherein the grid comprises: a grid body; and a plurality of air path components disposed on an outer circumference of the grid body with a predetermined angle of inclination to form an air passage to the air outlet. A cyclone-type dust collecting device according to claim 2, wherein the grid comprises: a grid body; I a plurality of air path components arranged on an outer circumference of the grid body at a predetermined angle of inclination to form an air passage I to the air outlet; and a dirt-blocking part which is arranged on the lower part of the grid body. I 20 6. A cyclone-type dust collecting device according to claim 2, wherein the means for rotating and supporting the grid is provided with: a support part arranged in the center of the air outlet of the cylindrical main body through an I a plurality of ribs projecting from an inner surface of the air outlet; and wherein a rotating part is provided with a first end that is rotatably supported by arranging a bearing and with a second end protruding through the grating and is attached to a lower part of the grating. A cyclone-type dust collecting device according to claim 2, wherein a fine dust filter assembly is disposed between the upper surface of the cylindrical main body and cover to filter fine dust. - 15 - A cyclone-type dust collecting device according to claim 7, wherein the fine dust filter composition comprises: a fine dust filter; and a filter frame with a lower lattice construction, to receive and support the fine dust filter. 9. A cyclone-type dust collecting device according to claim 7, wherein the upper surface of the cylindrical main body runs obliquely downwards from a radial outer circumference to a middle part. 10. Cyclone-type dust collecting device suitable for use in a vacuum cleaner and comprising: a cyclone body with an air inlet and an air outlet, suitable for forming a swirling air stream of dust-laden air sucked in through the air inlet; a dust collection which is removably connected to the cyclone body intended to receive dust and dirt separated from the air; a grid disposed near the air outlet and within the cyclone body; wherein the grid is provided with at least one air path component; and wherein the air path component is inclined. A cyclone-type dust collecting device according to claim 10, wherein a front edge of the air path component is disposed radially within the rear edge of the air path component. The cyclone-type dust collecting device according to claim 10, wherein the grid rotates. 13. A cyclone-type dust collecting device according to claim 12, wherein the swirling air flow causes the grid to rotate in the direction corresponding to the direction of rotation of the swirling air flow. The cyclone-type dust collecting device according to claim 12, further comprising a rotating part which is provided with a bearing at the first end and whose second end is rigidly connected to the grid. A cyclone-type dust collecting device according to claim 14, wherein the bearing is also connected to a support member connected to the cyclone body. 16. A cyclone type dust collecting device suitable for use with a vacuum cleaner and comprising: means for forming an air swirl of air contaminated with dirt; Means for receiving dust and dirt separated from the air by a centrifugal force of the air swirl; and means for rotating a grid disposed within a cyclone body. A cyclone-type dust collecting device according to claim 16, further comprising means for supporting the rotating grid. 18. A cyclone-type dust collecting device according to claim 16, further comprising a fine dust filtering means. The cyclone-type dust collecting device according to claim 16, further comprising a means for dropping fine dust into a dust collecting device. I 25 20. The cyclone-type dust collecting apparatus according to claim 16, further comprising means for minimizing flow along the rotating grid.