KR950004663Y1 - Vacuum cleaner of cyclone system - Google Patents

Abstract

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Description

Cyclone vacuum cleaner

1 is a block diagram for explaining the configuration of a general cyclone vacuum cleaner.

2 is a side cross-sectional view showing a general cyclone vacuum cleaner.

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a side sectional view showing a cyclone vacuum cleaner according to the present invention.

5 is a cross-sectional view taken along the line B-B in FIG.

* Explanation of symbols for main parts of the drawings

3: inlet port 15: casing

21: means of preventing contamination rise 22: hollow

The present invention relates to a cyclone vacuum cleaner, in particular a cyclone vacuum cleaner that improves the suction power of contaminants, prevents backflow of contaminants when the power is turned off and increases the dust collection capacity. It is about.

Conventionally, various types of vacuum cleaners using the principle of cyclone are known, and one embodiment of a typical cyclone vacuum cleaner will be described with reference to Patent Application No. 231919 in the following.

As shown in Figs. 1 to 3, a longitudinal semicircular casing (Casingm 15) is divided into upper and lower portions by a partition wall 14, and a bypass motor (by-pass motor), which is a wet motor, in the center of the upper portion. , 1), and a cylindrical deodorizing filter 9 is installed around the motor 1, and the lower portion of the casing 15 has a primary cross-section cyclone recovery tank 6 in a circular cross section. In the lower part of 15), the primary cyclone recovery tank 6 is formed by the inside of the casing 15 and the partition wall 14 in a circular cross section, and the secondary cyclone of the conical shape downward in the primary cyclone recovery tank 6 is formed. (4) was installed so that the upper part of this collection | recovery tank 4 may be located in the lower part of the motor 1. As shown in FIG. In addition, between the lower part of the motor 1 and the upper part of the secondary cyclone to install a motor protective foam filter (2) to filter out the object that may be harmful to the motor, one side of the primary recovery tank (6) The inlet (3) is provided on the lower side of the casing (15) to inhale air and contaminants, and on the partition (14) forms an isolated space around the filter unit (2) to contain the tax solution to be supplied. The tank 8 is provided.

Further, according to FIG. 1, it can be seen that a driving circuit 12 for controlling the motor 1 is provided, and that there is an external power source 13 for supplying power to the driving circuit 12.

When dry in a general cyclone vacuum cleaner as described above, the two-phase flow of air and contaminants sucked through the inlet (3) is the primary and secondary cyclones (Cychrolne; 4, 6), the filter (2), After being purified through the motor 1 and the deodorizing filter 9, clean exhaust is performed through the exhaust port 10 formed in the upper portion of the casing 15. At this time, the back pressure generated by the operation of the motor 1 acts on the washing tank 8 to discharge the washing liquid, and the intake for cooling the motor is formed on the casing 15 at the upper portion of the motor 1. 11) flows through.

In addition, the lower portion of the secondary cyclone (4) is provided with a dust hopper (Dust Hopper, 5) for collecting the dust collected in the recovery tank (4).

Therefore, such a vacuum cleaner is a cyclone-type structure (4, 6) is applied to the main body of the vacuum cleaner, the cyclone structure adopts the principle of separating the contaminants in the air sucked by the centrifugal force as is known. In addition, the liquid storage tank 8 is provided in the main body to be used for wet cleaning as well as dry cleaning.

A general cyclone vacuum cleaner having the above configuration operates as follows.

First, when the bypass motor 1 is driven by the drive circuit 12 during dry use, the dry contaminants introduced through the nozzle (not shown) are transferred to the primary cyclone recovery tank 6 of the main body through the suction port 3. It flows inside and flows through the cyclone wall of the recovery tank 6, that is, the inner wall of the casing 15, by the rotational force of the motor as shown by the arrow in FIG. Collected on the wall, and the remaining fine dry contaminants and air are introduced into the secondary cyclone (4) through the inlet (7) of the secondary cyclone (4) by the rotational centrifugal force of the motor (1) as shown by the arrow in FIG. Fine dry contaminants are collected on the main wall and collected by the dust hopper 5 as it flows through the cyclone wall of the cyclone 4, and thus the purified air, i. Inside the car cyclone (4) It is exhausted to the motor 1 side through the extended vortex finder 16. At this time, the purified air through the vortex finder 16 is once again purified by passing through the po filter 2, which is a motor protection filter, and after being introduced into the motor 1 chamber, passes through the deodorizing filter 9 After removing the dust and unpleasant smell is exhausted to the outside through the exhaust port (10).

The principle of secondary purification in the secondary cyclone (4) during the purification of such contaminants is as follows.

That is, the two-phase flow of contaminants and air from the primary cyclone recovery tank 6 through the inlet 7 is subjected to centrifugal force by the rotation of the motor 1 so that it rapidly rotates in the cyclone of the cyclone 4. In this case, the contaminants in the secondary fluid are generally denser than air, so they are concentrated on the cyclone wall by receiving a greater centrifugal force, and are rotated down the cyclone wall and are collected downward in the dust hopper 15 under the influence of gravity. will be.

Through this process, when the air in the secondary recovery tank 4 is purified and purified air, the air filter 2 is sucked into the motor room through the vortex finder 16 by the rotational suction input of the motor 1 again. It is once again purified by.

In addition, even if it is intended to use wet, the general operation for purification is the same as that of a dry cleaner. Especially, since the cyclone method is adopted, the recovery capacity of the tax solution is as dry as compared to the conventional recovery device by the suction power of the motor. Since it has a recovery efficiency of, the body can be made smaller. On the other hand, since the bypass motor 1, which is a wet motor, is mounted and used in the main body, moisture does not come into contact with the electric device of the motor 1 in the wet cleaner, thereby ensuring electrical safety.

However, in the general cyclone vacuum cleaner as described above, as shown in FIG. 2 and FIG. 3, when the contaminant flows into the casing 15 through the suction port 3, the casing 15 The lower recovery tank (6) acts as a primary cyclone and contaminants are collected in a two-dimensional parabola at the bottom of the gray casting tank (6).

As the cleaning operation continues, both ends of the parabola reach the inlet 3, as shown in FIG. 2, so that the mixing and contaminants at the inlet 3 are severely shaken.

Due to such fluctuations of the contaminants, not only the suction power of the vacuum cleaner is lowered, but also when the power of the vacuum cleaner is turned off, the contaminants are reversed and the dust collecting capacity is limited.

An object of the present invention is to provide a cyclone vacuum cleaner to improve the suction power of the contaminants.

Another object of the present invention is to provide a cyclone-type vacuum cleaner that can prevent backflow of contaminants when the power is turned off.

Another object of the present invention is to provide a cyclone vacuum cleaner to increase the dust collecting capacity.

In order to achieve the object of the present invention, there is provided a cyclone-type vacuum cleaner, characterized in that provided with a contaminant rise preventing means on the inner wall of the casing that is directly below the suction port.

The contaminant rise preventing means comprises an annular (annular) diaphragm having a hollow formed in the middle portion and having a predetermined width.

Hereinafter, the cyclone vacuum cleaner according to the present invention will be described according to the embodiment shown in the accompanying drawings.

4 is a side cross-sectional view showing a cyclone vacuum cleaner according to the present invention, and FIG. 5 is a cross-sectional view taken along line B-B of FIG.

As shown in the drawing, the cyclone vacuum cleaner according to the present invention, in the general cyclone vacuum cleaner shown in Figs. 2 and 3, the casing (directly below the inlet 3) ( 15 is provided with a contaminant rising preventing means 21 on the inner wall.

The contaminant rise preventing means 21 is characterized in that the hollow 22 is formed in the middle portion and is an annular diaphragm having a predetermined width w.

The contaminant rise preventing means 21 is not limited to the embodiment shown in the drawings, and any constitution may be used as long as it prevents the rise of contaminants.

In the drawings, the same reference numerals are given to the same parts as the prior art configurations.

The cyclone vacuum cleaner according to the present invention configured as described above will perform the cleaning operation according to the same principle as the vacuum cleaner of the general cyclone system shown in FIGS. The characteristic operation of the design will be described in more detail.

That is, in the case of using the cyclone vacuum cleaner according to the present invention as a dry type, when the bypass motor 1 is driven, dry contaminants introduced through the nozzles are discharged from the primary cyclone recovery tank 6 of the main body through the suction port 3. It is introduced into the inside and flows through the cyclone wall of the recovery tank 6 by the rotational force of the motor 1. At this time, relatively large contaminants are collected on the main wall by the centrifugal force, and the remaining fine dry contaminants and air are secondary. Through the inlet 7 of the cyclone 4, it flows into the secondary cyclone 4 and flows through the cyclone wall of the cyclone 4 by the centrifugal force of the motor 1, whereby fine dry contaminants collect on the main wall surface and are dusted. Collected by the hopper 5, this secondary purified air, ie the purified air, is passed through the vortex finder 16 extending from the bottom of the motor 1 into the secondary cyclone 4. To the side.

At this time, the purified air through the vortex finder 16 is once again purified by passing through the motor filter filter filter 2, and after entering the motor (1) chamber through the deodorizing filter (9), finer dust And after removing the unpleasant odor is exhausted to the outside via the exhaust port (10).

The principle of the secondary purification in the secondary cyclone 4 during the purification of the contaminants is as follows.

That is, the two-phase flow of contaminants and air from the primary cyclone recovery tank 6 through the inlet 7 is subjected to centrifugal force by the rotation of the motor 1 so that it rapidly rotates in the cyclone of the cyclone 4. At this time, since the contaminants in the two-phase fluid are generally denser than air, they are concentrated on the cyclone wall by receiving a greater centrifugal force, and are rotated along the cyclone wall to be lowered downward and collected in the dust hopper 15 by gravity. will be.

Through this process, when the air in the secondary recovery tank 4 is purified and purified, the air filter 2 is sucked into the motor room through the vortex finder 16 by the rotational suction force of the motor 1 again. It is once again purified by.

In the conventional cleaning operation as described above, since the contaminant rise preventing means 21 is provided on the inner wall of the casing 15 which is directly below the suction port 3, the form of the contaminant at the beginning of the operation is different from that of the conventional case. The same parabolic shape (p) is formed, but as time passes, the vehicle gradually moves inward on the lower surface of the contaminant rising prevention means (21). ), And the inner edge of the joint is changed to form, where the state of the primary cyclone dust collection capacity is the maximum.

As described above, the cyclone vacuum cleaner according to the present invention includes a contaminant rise preventing means on the inner wall of the casing, which is directly below the intake port where the contaminants are inhaled. There is an advantage to improve, and when the power is off (off), not only prevents the backflow of contaminants by the contaminant rise preventing means, but also has the effect of increasing the dust collecting capacity.

Claims (2)

Cyclone vacuum cleaner, characterized in that the inner wall of the casing (15) that is directly below the suction port (3) provided with a contaminant rise preventing means (21). The cyclone vacuum cleaner according to claim 1, wherein the contaminant rise preventing means (21) is an annular diaphragm having a hollow (22) formed at an intermediate portion thereof and having a predetermined width (w).