KR20020082630A - device for removing static electricity of cyclone type dust collector - Google Patents

Abstract

PURPOSE: An apparatus for removing a static electricity of a cyclone dust collecting device is provided to enhance an electrical charge preventing property of a cyclone body by applying an electrical conductivity at the cyclone body. CONSTITUTION: A cyclone body(100) is provided with an air intake port for introducing a waste and air into a cylindrical body, and an air discharging port for discharging the waste and air. An intake passage is communicated with the air intake port, and guides the absorbed air and waste from an exterior into an inside of the cyclone body. A discharging passage is communicated with the air discharging port, and guides the separated air and waste into the exterior. When an electrical charge is accumulated at the cyclone body, a discharge deriving unit(70) for discharging the static electricity from the cyclone body is installed inside the cyclone body. A fan/motor assembly is communicated with one end of the cyclone body, and generates a suction force.

Description

Static eliminator for cyclone dust collector {device for removing static electricity of cyclone type dust collector}

The present invention relates to a cyclone dust collector, and more particularly, to a static electricity removing device of a cyclone dust collector to remove the static electricity generated in the cyclone body of the cyclone dust collector.

In general, the cyclone dust collector is a device using a cyclone principle to discharge the air out of the pollutants that rotate with the air by using a centrifugal force, and to separate only the pollutants from the air, which is mainly vacuum for home use. It is adopted by vacuum cleaner and is used.

The cyclone dust collector as described above has been proposed in various forms to improve the dust collection performance, as an example of the "cyclone cyclone dust collector for vacuum cleaners" filed in Korea by the present applicant (Domestic patent application 10-2000-48088) will be described with reference to the conventional cyclone dust collector (see Figs. 1 and 2).

1 is a side cross-sectional view showing a main portion of an example of a conventional cyclone dust collector, and FIG. 2 is a perspective view of a main portion of the cyclone body structure of FIG. 1, and the structure and operation of a conventional cyclone dust collector will be described with reference to the drawings. Is as follows.

As shown, the conventional cyclone dust collector has a substantially cylindrical cyclone body 20 having an air inlet through which air and contaminants are introduced from the outside of the upper side of the cyclone body, and the upper side of the cyclone body 20. The suction passage 10 connected in the tangential direction and an air outlet through which the air introduced into the cyclone body 20 is discharged are formed in the central portion thereof, and detachably mounted at the upper end of the cyclone body 20. An upper cover 30 forming the upper surface of the clone body 20 and a dust collecting filter 40 installed at an air outlet of the center of the upper cover 30 to filter fine dust from the flow air to discharge only pure air; The discharge passage 50 is formed to communicate with the dust collecting filter 40 from the outside of the cyclone body 20, and the fan / motor assembly 60 for generating a suction force through the discharge passage 50 .

On the other hand, the inner lower portion of the cyclone body 20 has a disk-like formed with a plurality of dust inlet hole 26 formed in the outer peripheral portion to partition the dust collecting portion 29 for collecting contaminants that settle after entering into the cyclone body 20 The partition plate 25 is installed, and the partition plate 25 is formed by two pairs of hinge brackets 22 rotatably coupled to each other by a pair of hinge brackets 22 opposite to the lower side wall of the cyclone body 20. It consists of semi-circular part 25a, 25b.

In addition, the engaging jaw 21 for supporting the semicircular portions 25a and 25b of the partition plate 25 is formed inside the sidewall of the cyclone body 20, and the engaging jaw 21 is provided by the engaging jaw 21. The partition plate 25 is limited to rotate downward, and can rotate only in one direction.

Referring to the operation of the conventional cyclone dust collector made of such a configuration as follows.

When the cyclone dust collector is operated, suction force is generated by the operation of the fan / motor assembly 60, and external air and contaminants are introduced into the cyclone body 20 along the suction flow path 10.

Air and contaminants introduced into the cyclone body 20 through the suction flow path 10 are spirally rotated and descend along the inner wall surface of the cyclone body 20, and relatively heavy contaminants continue to descend by centrifugal force. To be collected in the dust collector 29 through the dust inlet hole 26 of the partition plate 25 installed under the cyclone body 20, and the air and fine dust having a relatively small weight are collected by the suction force. ) Will flow to the side.

Subsequently, the fine dust contained in the flow air is filtered by the dust collecting filter 40, and only air passes through the dust collecting filter 40 and is discharged to the fan / motor assembly 60 through the discharge passage 50.

On the other hand, if you want to remove the dirt, such as dust collected in the dust collector 29 of the lower cyclone body 20, the user separates the cyclone body 20 from the body (not shown) and then reverse the partition plate The semicircular portions 25a and 25b of 25 are rotated by their own weight so that the dust collector 29 is opened, and contaminants fall off and removed.

However, such a conventional cyclone dust collector, when the air and contaminants are inhaled into the cyclone body by the operation of the cyclone dust collector, to the high-speed rotary air flow, such as swirl flow and discharge air flow acting in the cyclone body Due to the contact between the contaminants and friction, static electricity is generated therein.

In this case, since the cyclone body 20 is mostly made of a synthetic resin material, which is an insulator, the static electricity accumulated in the cyclone body 20 is maintained in a charged state without moving to the other side.

Therefore, when the user wants to separate the cyclone body 20 from the body in order to remove the contaminants collected in the cyclone body 20, the electric shock is accumulated due to the static electricity accumulated in the cyclone body 20. As this phenomenon is repeated, the user may cause discomfort or fear caused by static electricity.

In addition, when the user wants to remove the contaminants collected inside the cyclone body 20, the contaminants cling to the cyclone body 20 due to the attraction due to static electricity has had a very troublesome removal work.

Such static electricity can reduce the amount of static electricity generated in the cyclone body by forming the material of the cyclone body with a metal having excellent electrical conductivity. However, when the cyclone body is formed of a metal material, there are the following problems. .

First, when the cyclone body is formed of a metal material, there is a problem in that the production cost is increased and the manufacturing process and processing operations are relatively complicated and the productivity is low compared to the manufacture of the synthetic resin.

Second, in order for the user to easily measure the amount of contaminants trapped in the cyclone body and simplify the cleaning of the cyclone body, it is desirable to form the cyclone body as a light and transparent material. There was a problem that can not.

The present invention has been made to solve the conventional problems as described above, the static removal device of the cyclone dust collector to increase the removal performance of static electricity generated in the cyclone body while maintaining the advantages of the conventional cyclone body as it is It is intended to provide.

1 is a side cross-sectional view showing a main portion of an example of a conventional cyclone dust collector;

2 is a perspective view illustrating main parts of the cyclone body structure of FIG. 1;

3 is a partially cutaway perspective view of a cyclone body showing a preferred embodiment of the static eliminating device according to the present invention;

Figure 4 is a plan sectional view and enlarged view of the cyclone body of Figure 3;

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

29..dust collector, 70..discharge electrode,

80 .... compartment plate, 86 .... dust inlet,

100 ... cyclone body.

In order to achieve the above object, according to the present invention, the air inlet having electrical conductivity and transparency, capable of introducing air and contaminants in the tangential direction of the cylindrical body, and the air contaminated with the contaminants in the cyclone body, A cyclone body having an air outlet for discharging; A suction passage communicating with the air inlet of the cyclone body to guide air and contaminants sucked from the outside into the cyclone body; A discharge passage communicating with the air outlet to guide the pollutant and the centrifuged air to the outside in the cyclone body; Discharge inducing means installed inside the cyclone body to induce discharge between the inner surface of the cyclone body when static electricity of a predetermined charge voltage is accumulated in the cyclone body; It provides a static electricity removing device of the cyclone dust collector comprising a fan / motor assembly which is in communication with one end of the discharge passage to generate a suction force.

Here, the discharge inducing means is made of a material far from the charging sequence with respect to the material of the cyclone body and the dust collection chamber under the cyclone body to collect the contaminants settled through the dust inlet provided on the outer periphery It comprises a partition plate for separating and separating the discharge electrode made of a conductive material extending radially outward from the edge of the dust inlet hole so that the end portion thereof is spaced apart from the inner surface of the cyclone body by a predetermined interval.

According to the present invention, the cyclone body has electrical conductivity close to the metal, and thus the antistatic performance of the cyclone body is improved, thereby reducing the generation of static electricity in the cyclone body.

In addition, when the static electricity generated in the cyclone body reaches a predetermined charging voltage or more, the cyclone body is discharged by the discharge electrode between the partition plate having the opposite polarity charge and the cyclone body. It maintains a low charge voltage state that does not generate an electric shock by.

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

In the following description, for the main components of the present invention, reference is made to the conventional technology described above with reference to Figs. 1 and 2, and the detailed description thereof is omitted.

Figure 3 is a partially cutaway perspective view of a cyclone body showing a preferred embodiment of the electrostatic removal device according to the present invention, Figure 4 is a cross-sectional plan view and main portion enlarged view of the cyclone body of FIG.

As shown in the figure, the greatest feature of the present invention is to give the cyclone body 100 an electrical conductivity to improve the antistatic performance of the cyclone body 100 itself.

In addition, the material of the partition plate 80 installed inside the cyclone body 100 is formed of a material far from the cyclone body 100, and the dust inlet hole 86 of the partition plate 80 is formed. By discharging the discharge electrode 70, charges of opposite polarity are charged to the partition plate 80 and the cyclone body 100, and the static electricity accumulated in the cyclone body 100 by the discharge accordingly. Will be removed.

This will be described in more detail as follows.

First, in order to impart electrical conductivity to the cyclone body 100 made of a unique insulator made of a conventional transparent synthetic resin material, it can be achieved by adding a conductive material to the material forming the cyclone body 100, which is illustrated in FIG. 4. If described with reference to:

The cyclone body 100 is made of ABS by adding a fine powder of carbon black 100a, which is one of materials having antistatic properties, to a synthetic resin material having transparency such as ABS resin 100b at a weight ratio of 0.1 to 0.3%. The resin 100b and the carbon black 100a are mixed, and the mixture is injection molded into a predetermined shape by using a molding equipment such as a press injection machine.

In this case, the synthetic resin material for forming the cyclone body 100 may be any one or combinations of the synthetic resin material having transparency, such as PVC, as well as the ABS resin 100b, and the synthetic resin, which is an insulator. As a material capable of imparting antistatic properties to a material, any one or combination of materials such as metal powder such as copper or silver, metal fiber, surfactant, etc., or a combination thereof may be processed into a fine powder. Can be.

In addition, by appropriately adjusting the mixing ratio of the synthetic resin material and the antistatic material according to the characteristics of each mixed material, it is possible to appropriately control the transparency, processability, electrical conductivity, etc. of the cyclone body 100.

On the other hand, according to the above, as the inside of the cyclone body 100 made of a transparent ABS resin (100b) material is formed a structure containing a carbon black (100a) of a predetermined amount or less having a fine size, the conventional Like the cyclone body 20 (refer to FIG. 1) made of only a synthetic resin material, the amount of contaminants collected in the cyclone body 100 may be transparent enough to identify the user.

In addition, the surface electrical resistance of the cyclone body 100 according to the present invention is 10 ⁶ ~ by adding carbon black to the cyclone body of the conventional synthetic resin material having a low electrical conductivity as the surface electrical resistance is 10 ¹⁰ Ω / m ² or more 10 ⁸ Ω / m ^{2 It} is possible to maintain, the surface electrical resistance of the cyclone body 100 is maintained in the state of 10 ⁶ ~ 10 ⁸ Ω / m ² by the static electricity to the cyclone body 100 Is generated, the static electricity accumulated in the cyclone body 100 is moved to another object or discharged by contact with a main body (not shown) in which the cyclone body 100 is installed or discharge by a separate discharge inducing means. It is easy to make it.

In addition, as a method for imparting electrical conductivity and antistatic property to the conventional cyclone body 100 made of synthetic resin material, which is an insulator, the non-conductive synthetic resin having transparency similar to the conventional cyclone body 20 in addition to the aforementioned method. After manufacturing a cyclone body of a predetermined shape as ABS resin or PVC material, and applying an antistatic solution containing a material having antistatic performance to the inner and outer circumferential surfaces thereof, the surface of the cyclone body is electrically conductive. It is also possible to form a coating film.

As described above, by imparting electrical conductivity to the cyclone body 100, the antistatic performance of the cyclone body itself may be improved, and the rate of static electricity generation may be reduced.

On the other hand, by further installing the discharge inducing means according to the present invention in the above-described cyclone body 100 can further increase the performance of removing static electricity, the structure of the discharge inducing means with reference to Figures 3 and 4 The explanation is as follows.

The discharge inducing means is provided with a plurality of discharge electrodes 70 having a thin needle structure of a metal material having electrical conductivity at regular intervals along the edge of the dust inlet hole 86 of the partition plate 80.

In more detail, one end of the discharge electrode 70 is fixed on the outer periphery of the dust inlet hole 86 of the partition plate 80, and the other end thereof is radially outer side (the cyclone body of the dust inlet hole 86). (100) is installed to face the inner side.

In this case, the material of the partition plate 80 is preferably formed of a material such as nylon, such as nylon, the material of the cyclone body 100, the material far away from the charge sequence.

The reason is that ABS resin or PVC material tends to be charged with "-" charge due to its charging characteristics, whereas nylon has a strong tendency to be charged with "+" charge. This is because when the static electricity is generated, the cyclone body 100 is charged with "-" charge and the partition plate 80 is charged with "+" charge.

Therefore, by forming the material of the cyclone body 100 and the partition plate 80 far away from each other in the charging sequence, when the static electricity is generated, charges of opposite polarity are applied to the cyclone body 100 and the partition plate 80. When the charge reaches a predetermined charging voltage, the cyclone body and the partition plate 80 are discharged, and the static electricity accumulated in the cyclone body by the discharge can be removed.

On the other hand, the distance (L) between the discharge electrode 70 end portion and the inner surface of the cyclone body 100 is preferably designed to within 2mm.

The reason for this is that when the human body comes into contact with an object that is charged with static electricity in a relative humidity environment of 50 to 60%, the charging voltage of the static electricity, which can cause an electric shock due to static electricity in the human body, is 3 to 5 [kW]. For example, when the charging voltage of the static electricity charged in the cyclone body 100 reaches 3 to 5 [kW], when the distance between the discharge electrode 70 and the cyclone body 100 is 2 mm or less, between the two objects, This is because discharge can occur actively.

On the other hand, the discharge electrode 70 is preferably formed of a material having excellent electrical conductivity such as copper (Cu) or silver (Ag) in order to increase the discharge effect with the cyclone body (100).

Referring to the static elimination action by the electrostatic eliminating device according to the preferred embodiment of the present invention having such a configuration as follows.

When the cyclone body 100 is installed in the main body, when the cyclone dust collector is operated, the dirt is sucked into the cyclone body, and due to the contact and friction between the contaminants by the high-speed rotary airflow acting in the cyclone body, Static electricity is generated in the clone body.

On the other hand, the amount of static electricity generated in the cyclone body 100 is a significant difference in the amount of generation due to external factors, such as humidity, for example, the environment of use of the cyclone dust collector has a high humidity of the static electricity generated in the cyclone body When the amount is small, the electrostatic elimination action is explained as follows.

The bottom surface of the cyclone body 100 or a part of the cyclone body is maintained in contact with a part of the body, and thus the static electricity accumulated in the cyclone body is moved to the body side through the bottom surface, and the body is grounded and made of static electricity. The static electricity is removed instantaneously by electrically neutralizing on the main body.

On the other hand, when the use environment of the cyclone dust collector is dry to explain the static electricity removal action when the amount of static electricity generated in the cyclone body is as follows.

When static electricity is generated in the cyclone body 100, the partition plate 80 is made of nylon, and the "+" charge is charged to the partition plate 80 in consideration of the charging sequence of nylon.

On the other hand, the cyclone body 100 is an ABS material, when considering the charging sequence of the ABS material, "-" charge is charged to the cyclone body.

As described above, when the charge of the opposite polarity starts to be charged to the cyclone body 100 and the partition plate 80, respectively, and the charge voltage of the static electricity accumulated for a predetermined time reaches approximately 5 [m], a predetermined separation distance ( L) As the discharge occurs as a discharge spark and sound between the discharging end 70 of the discharge electrode 70 and the inner surface of the cyclone body, the charging voltage of the static electricity accumulated in the cyclone body and the partition plate 80 is zero. do.

In addition, the static electricity generated in the cyclone body 100 and the partition plate 80 by the continuous operation of the cyclone dust collector is repeated for a period of time to discharge the discharge, and in this process the cyclone body (100) ) Maintains a low charged voltage state that does not cause an electric shock by static electricity to the human body.

On the other hand, the embodiments of the present invention as described above are not limited to this configuration is configured to help the understanding of the present invention, various modifications are possible within the scope without departing from the spirit of the present invention.

As described in detail above, according to the present invention, by providing an antistatic property to the cyclone body made of a transparent synthetic resin material, which is an insulator, the conductors of the conventional cyclone body made of a synthetic resin material, while maintaining the advantages such as transparency and low cost It has an electrical conductivity close to, so that the movement and discharge of static electricity to other objects can be easily maintained.

In addition, when the static electricity generated in the dust collector reaches a predetermined charging voltage or more, discharge occurs between the discharge electrode and the inner surface of the cyclone body, thereby further improving the elimination performance of the static electricity generated in the cyclone body. .

Claims (4)

Cyclone body having electrical conductivity and transparency, and having an air inlet for introducing air and contaminants in the tangential direction of the cylindrical body and an air outlet for discharging contaminants and centrifuged air in the cyclone body. Wow; A suction flow passage communicating with an air inlet of the cyclone body to guide air and contaminants sucked from the outside into the cyclone body; A discharge passage communicating with the air outlet to guide the pollutant and the centrifuged air to the outside in the cyclone body; Discharge inducing means installed inside the cyclone body to induce discharge between the inner surface of the cyclone body when static electricity of a predetermined charge voltage is accumulated in the cyclone body; And a fan / motor assembly configured to communicate with one end of the discharge passage to generate a suction force. The method of claim 1, The discharge inducing means is formed of a material far from the charging sequence with respect to the material of the cyclone body, and separates and separates the dust collecting chamber under the cyclone body so as to collect the contaminants settled through the dust inlet provided on the outer circumference. Partition plate, And a discharge electrode made of a conductive material extending radially outward from an edge of the dust inflow hole and spaced apart from the inner surface of the cyclone body by a predetermined distance. The method of claim 2, The distance between the end of the discharge electrode and the inner surface of the cyclone body is less than 2mm electrostatic removal device of the cyclone dust collector. The method of claim 2, The discharge electrode is a static eliminator of the cyclone dust collector, characterized in that the needle structure of a metal material having excellent electrical conductivity.