KR100767663B1 - device for preventing electrification of dust-envelope for cyclone dust collector - Google Patents

Abstract

The present invention relates to an antistatic device of a cyclone dust collector for a cyclone dust collector, the present invention is provided with a suction force generating means and a dust collector in the main body to generate a suction force by the suction force generating means to generate air and contaminants inside the cyclone body A cyclone dust collector which collects contaminants separated from air by centrifugal force in the cyclone body and collects in the cyclone body, wherein the dust collector has electrical conductivity and the amount of contaminants collected therein. It is formed to have a transparency so that it can be distinguished, and the cyclone dust collector, characterized in that it is provided with a humidification means to discharge the atomized humidifying particles inside the dust collecting chamber is installed the dust collecting container to high-humidity around the dust collecting container The antistatic device for dust collector is provided, and the transparency and low cost of dust collector made of synthetic resin material The electrical conductivity close to the conductor can be maintained while maintaining the point, and the antistatic performance of the dust collector can be improved.In addition, the moisture supply to the inside of the dust chamber is controlled according to the humidity conditions of the dust chamber inside the cyclone dust collector. By maintaining the proper high-humidity environment to prevent the charging of the dust collector.

Cyclone dust collector, dust collector, humidification means.

Description

Device for preventing electrification of dust-envelope for cyclone dust collector

1 is a schematic longitudinal sectional view showing an example in which a general cyclone dust collector is applied to a vacuum cleaner;

Figure 2 is an enlarged cross-sectional view of the main portion showing the dust collector installation structure of FIG.

Figure 3 is a longitudinal sectional view schematically showing the installation state of the dust collector and the humidifying means of the cyclone dust collector according to an embodiment of the present invention,

Figure 4 is an enlarged cross-sectional view showing the installation structure of the dust collecting container and the humidifying means of FIG.

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

1 .... main body, 2 .... dust collection room,

15,30 .... dust collector, 50 .... reservoir,

51 .... water supply, 52 .... water supply

60 ... auxiliary tank, 65 ... discharge outlet,

70 .... ultrasonic oscillator.

The present invention relates to a cyclone dust collector, and more particularly, to an antistatic device of a cyclone dust collector dust collector for improving the antistatic performance of the cyclone dust collector.

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

1 is a schematic longitudinal sectional view showing an example in which a general cyclone dust collector is applied to a vacuum cleaner, and the structure and operation of a conventional cyclone dust collector will be described with reference to the drawings.

As illustrated in FIG. 1, a dust collecting chamber 2 is separated and partitioned by a partition wall 3 on one side of the main body 1 of the vacuum cleaner, and a cylindrical cyclone body inside the dust collecting chamber 2 ( 11 is positioned in the vertical direction, the suction pressure is generated by the operation of a motor (not shown) on one side of the upper surface of the cyclone body 11 through the connection hose 5 of the vacuum cleaner into the body 1 A suction flow path 12 is formed to suck air and contaminants sucked in the cyclone body 11 in a tangential direction, and an upper portion of the cyclone body 11 is sucked into the cyclone body 11. An air discharge passage 13 is formed to discharge the air separated from the pollutant by centrifugal force upward from the air and the pollutant, and the air sucked into the cyclone body 11 is formed at the center of the lower surface of the cyclone body 11. Minutes by centrifugal force among contaminants The pollutant discharge passage 14 is formed to discharge the polluted substances downward, and the pollutant discharge passage 14 is discharged through the pollutant discharge passage 14 in a state located directly below the cyclone body 11. Dust collector 15 is detachably coupled to collect contaminants.

Referring to the operation of the cyclone dust collector made of this configuration is as follows.

When the cyclone dust collector is operated, a motor (not shown) is operated to generate a suction force inside the cyclone body 11, and by this suction force, the contaminants together with the air through the suction passage 12 through the cyclone body. (11) is sucked into.

At this time, the contaminated air sucked in the tangential direction with respect to the cyclone body 11 through the suction passage 12 generates a centrifugal force while turning (orbiting) the inner wall of the cyclone body 11.

Therefore, since the air having a relatively light weight receives less centrifugal force, the air gathers into the central portion of the cyclone body 11 to form a whirl, forming a flow (discharge airflow) in the direction of the air discharge flow path 13, while the air flows through the air discharge flow path. Ejected through 13.

On the other hand, contaminants that are heavier than air receive relatively more centrifugal force and flow along the inner wall surface of the cyclone body 11, and are eventually collected in the dust collector 15 installed on the pollutant discharge passage 14. If contaminants are collected in the analgesic 15 or more than a predetermined limit, the dust collecting container 15 is separated from the inside of the main body 1 to discard the contaminants, and then used again by being combined.

However, in general cyclone dust collector, when contaminants are sucked into the cyclone body by the operation of the cyclone dust collector, the contact between the pollutants by the high-speed rotary air flow such as the swirl flow and the discharge air that acts in the cyclone body. And static electricity is generated in the dust collecting container due to friction with the rotary airflow.

On the other hand, as shown in FIG. 2, since the bottom surface 15b of the dust collecting container 15 is in contact with the main body 10, the static electricity accumulated on the dust collecting bottom 15b moves toward the main body 10. To some extent, but due to the material of the dust collecting container 15 is made of synthetic resin which is an insulator, the static electricity accumulated on the side of the dust collecting container 15 and the handle 15a portion does not move to the main body 10 side. It will remain as it is.

For this reason, when the user grasps the dust collector handle 15a to separate and clean the dust collector 15 from the main body 1 in a dry state, the static electricity accumulated in the dust collector 15 and the handle 15a may be reduced. Due to the electric shock, this phenomenon is repeated, causing the user to feel discomfort or fear caused by static electricity.

On the other hand, the static electricity can form the material of the dust collector (15) with a metal material excellent in electrical conductivity to improve the antistatic performance, and also by collecting a high humidity surrounding environment using a cyclone dust collector (15) Although the charging of can be suppressed, in this case, there were the following problems.

First, when the dust collector is manufactured from a metal material having excellent electrical conductivity, the production cost of the dust collector is increased in comparison with that of the synthetic resin, and the production process and processing work are relatively complicated, resulting in low productivity.                         

Second, in order for the user to easily measure the amount of contaminants collected in the dust collecting container and simplify the cleaning operation of the dust collecting container, it is desirable to form the dust collecting container as a light and transparent material, which cannot be satisfied in the case of metal materials. There was this.

Third, in recent years, production sites have become increasingly environmental factors, such as high-speed machines and factory automation, which increase the heat load in the workplace, increase the temperature of the workplace, and lower the humidity. In the case of the cyclone dust collector employed in the vacuum cleaner, there is a problem that the charging of the dust collector 15 is further intensified due to the low humidity of the dust collecting chamber 2 in the main body 1 due to the operating heat of the motor. .

The present invention has been made to solve the above conventional problems, while maintaining the advantages such as transparency and low cost of the dust collector made of a conventional synthetic resin as it is, the charging phenomenon of the dust collector is intensified due to a low humidity environment An object of the present invention is to provide an antistatic device for a cyclone dust collector for preventing dust.

In order to achieve the above object, according to the present invention is provided with a suction force generating means and a dust collecting container inside the main body to generate a suction force by the suction force generating means to suck air and contaminants into the cyclone body and within the cyclone body. In a cyclone dust collector configured to collect contaminants separated from air by centrifugal force into a dust collecting container, the dust collecting container has electrical conductivity and transparency to identify the amount of contaminants collected therein. To provide an antistatic device of a cyclone dust collector for a cyclone dust collector, characterized in that it comprises a humidifying means for discharging the humidified particles to the inside of the dust collecting chamber in which the dust collecting container is installed to increase the humidity around the dust collecting container. will be.

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 longitudinal sectional view schematically showing the installation state of the dust collector and the humidifying means of the cyclone dust collector according to a preferred embodiment of the present invention, Figure 4 is an enlarged cross-sectional view showing the installation structure of the dust collector and the humidifying means of FIG. .

As shown in the figure, the biggest feature of the present invention is to install the dust collector (30) having electrical conductivity and transparency inside the main body (1), the dust collecting chamber (2) is installed The dust collecting container 30 is formed by forming a thin water film on the surface of the dust collecting container 30 by providing a humidifying means for supplying humidified particles atomized inside to create a high-humidity environment of the dust collecting chamber by the humidifying particles. By lowering the surface electrical resistance of the dust collector 30 to increase the antistatic performance.

This will be described in more detail as follows.

First, in order to impart antistatic property to a transparent dust collector, which is an insulator inherently made of a conventional synthetic resin material, it can be achieved by adding an electrically conductive material to a material forming the dust collector, thereby having electrical conductivity, which will be described with reference to FIG. 4. Is as follows.

The dust collecting container 30 is a fine material of carbon black 30a, which is one of materials having transparency, such as ABS resin 30b, and an antistatic property for imparting antistatic property to the dust collecting container 30, for example. The powder is mixed at a weight ratio of 100: 0.1 to 0.3% to form a mixture in which the ABS resin 30b and the carbon black 30a are mixed, and the mixture is injection molded into a predetermined shape by using a molding equipment such as a press injection machine. Is produced.

In this case, as the synthetic resin material forming the dust collecting container 30, any one or a combination of not only the ABS resin 30b but also a synthetic resin material having transparency such as acrylic and PVC can be used, and the insulator As a material capable of imparting antistatic property to a synthetic resin material, any one or combination of materials such as metal powders such as copper (Cu) and silver (Ag), metal fibers, surfactants, and the like, as well as carbon black 30a It can be used in the form of fine powder.

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 and the like of the dust collecting container 30.

On the other hand, according to the above, since the inside of the dust collector (30) made of a transparent ABS resin (30b) material is a structure containing a carbon black (30a) of a predetermined amount or less having a fine size, only synthetic resin material Like the conventional dust collecting container 15 (see FIG. 1), the amount of contaminants collected inside the dust collecting container 30 can be transparent enough for a user to identify the dust collecting material.

In addition, the surface electrical resistance of the dust collecting container 30 is 10 ⁶ to 10 ⁸ kW by adding carbon black 30a to the conventional synthetic resin dust collecting container having a surface electrical resistance of 10 ¹⁰ Ω / m ² or more. / m ² can be maintained, and when the surface electrical resistance of the dust collecting container 30 is maintained in a state of 10 ⁶ to 10 ⁸ kW / m ² , static electricity is generated in the dust collecting container 30, The static electricity accumulated in the dust collecting container 30 can be easily moved or discharged to another object by contact with the main body 1 provided with the dust collecting container 30 or grounding by a separate grounding means.

In addition, as a method for imparting electrical conductivity and antistatic property to a transparent dust collector made of a conventional synthetic resin material, which is an insulator, a predetermined shape as a non-conductive synthetic resin material having transparency similar to the conventional dust collector shown in FIG. After the dust collector is manufactured, a conductive coating film may be formed on the surface of the dust collector by applying and drying an antistatic liquid containing a material having antistatic performance on the inner and outer circumferential surfaces thereof.

On the other hand, by adding the humidifying means according to the present invention to the above-mentioned dust collecting container 30 to supply moisture to the dust collecting container 30 side by the humidifying means to install the dust collecting container 30, that is, inside the dust collecting chamber (2) By increasing the humidity, it is possible to further increase the antistatic performance of the dust collecting container 30, the structure of the humidifying means according to the present invention will be described with reference to Figs.

The humidifying means is installed in the main body (1) and the water storage tank 50 that can accommodate a predetermined amount of water (40) in the inside, and the water supply control member 52 provided on the lower side of the water storage tank (50) It is installed on the bottom surface of the auxiliary tank 60 to operate in conjunction with the operation of the cyclone dust collector and the auxiliary water tank 60 that can receive and receive a predetermined amount of water 40 in the reservoir 50 by And a through hole from an upper end surface of the auxiliary water tank 60 so as to discharge the water inside thereof into an atomized state and to discharge the humidified particles into the dust collecting chamber 2. It consists of the discharge port 65 extended through the partition 3 through 3a, and installed in the dust collection chamber 2 inside.
The water supply control member 52 is preferably installed to open and close at a portion in which the water tank 50 and the auxiliary water tank 60 communicate with each other, a valve or the like generally used to control the water supply may be adopted.

At this time, the reservoir 50 is provided with a water supply hole 51 that can be opened and closed at the upper end so that the user can supply water into the reservoir 50, the water level of the water 40 accommodated inside the reservoir 50 By forming the material of the reservoir 50 in a transparent material so that the user can easily identify, the user can detect the lack of water in the reservoir 50 to replenish the insufficient water without installing a separate level sensor for detecting the water level. You can do that.

In addition, on the partition 3 of the dust collecting chamber 2, the humidity of the dust collecting chamber 2 is detected and the humidity is electrically connected to the driving controller so as to apply the detected humidity signal to the driving controller (not shown). The sensor 80 is installed.

Thus, if the relative humidity in the dust collecting chamber 2 detected by the humidity sensor 80 is higher than the preset value in the drive control unit (90% or more), the drive control unit applies an off signal to the ultrasonic vibrator. On the other hand, when the relative humidity in the dust collecting chamber 2 detected by the humidity sensor 80 is lower than the value set in the driving control unit (less than 60%), the driving control unit is turned on (70). on) signal to operate the ultrasonic vibrator 70.

Referring to the operation of the present invention made of such a configuration as follows.

First, when the cyclone dust collector is operated in a state where the dust collecting chamber 30 is inserted into the dust collecting chamber 2 inside the main body 1, the cyclone body 11 is sucked with air and contaminants, thereby causing the Static electricity is generated in the dust collecting container 30 due to contact and friction between air and contaminants caused by the high speed rotary airflow acting in the clone body 11.

At this time, the amount of static electricity generated in the dust collecting container (2) is a significant difference in the amount generated according to the humidity conditions around the dust collecting container (2), the relative humidity in the dust collecting container (2) low humidity environment of less than 60% In one case, the low humidity signal sensed by the humidity sensor 80 in the dust collecting chamber 2 is applied to the drive control unit, and the drive control unit receiving the low humidity signal is supplied with an on signal to the ultrasonic vibrator 70. It is applied to operate the ultrasonic vibrator 70.

Subsequently, while the ultrasonic vibrator 70 is operated, the water contained in the auxiliary water tank 60 is converted into atomized humidified particles and discharged into the dust collecting chamber 2 through the discharge port 65.

As the humidifying particles are continuously supplied into the dust collecting chamber 2, the relative humidity in the dust collecting chamber 2 gradually changes to a high humidity state, and as time passes, the interior of the dust collecting chamber 2 has a high humidity close to a saturation state. It becomes                     

As such, as the interior of the dust collecting chamber 2 is in a high humidity state, a part of the humidifying particles are adsorbed on the surface of the dust collecting container 30 to form a thin conductive film on the surface of the dust collecting container 30, and the dust collecting container 30 The surface electrical resistivity of the dust collecting container 30 is lowered and the surface electrical resistivity of the dust collecting container 30 is lowered by the formation of a conductive layer formed by a water film on the surface. Will be.

When the humidifying particles are continuously supplied into the dust collecting chamber 2 by the operation of the humidifying means, and the relative humidity in the dust collecting chamber 2 becomes a high humidity state of 90% or more, the dust collecting chamber 2 which senses this A humidity signal of high humidity is applied to the driving control unit by the humidity sensor 80 inside, and the driving control unit receiving the high humidity signal applies an off signal to the ultrasonic vibrator 70 to stop the operation of the ultrasonic vibrator 70. do.

In addition, even when the relative humidity in the dust collecting chamber 2 is a high humidity environment of 90% or more when the first cyclone dust collector is operated, the high humidity humidity signal detected by the humidity sensor 80 in the dust collecting chamber 2 is similarly applied. By applying an off signal to the ultrasonic vibrator 70, the cyclone dust collector performs only a dust collecting operation and supplies moisture to the dust collecting chamber 2. The humidification operation is not performed.

Subsequently, when the heat generation load increases due to the operating heat of the motor due to the continuous operation of the cyclone dust collector, and the relative humidity in the dust chamber 2 is lowered to less than 60%, the ultrasonic vibrator 70 under the control of the drive controller. By supplying the humidified particles to the inside of the dust collecting chamber (2) by operating the high-humidity environment is formed around the dust collecting container 30, the dust collecting container 30 is suppressed the charging phenomenon, the dust collecting container 30 is therefore Maintains a low charged voltage state that does not cause electrical shock due to static electricity to the human body.

On the other hand, the embodiment of the present invention as described above is configured to help the understanding of the present invention is not limited only to the above-described embodiment, 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 imparting electrical conductivity to a dust collector made of transparent synthetic resin material, which is an insulator, electrical conductivity close to a conductor can be maintained while maintaining advantages such as transparency and low cost of dust collector made of a conventional synthetic resin material. It has a conductivity to improve the antistatic performance of the dust collector.

In addition, by controlling the water supply to the inside of the dust chamber according to the dust chamber humidity conditions inside the cyclone dust collector, by maintaining a suitable high-humidity environment inside the dust chamber, a conductive layer formed by a water film on the surface of the dust collector is formed. By lowering the surface electrical resistance, there is an effect of preventing the charging of the dust collector.

Claims (4)

A suction force generating means and a dust collecting container are provided inside the main body to generate suction force by the suction force generating means to suck air and contaminants into the cyclone body, and to remove the contaminants separated from the air by centrifugal force in the cyclone body. In the cyclone dust collector to collect, The dust collector is formed to have transparency so as to have an electrical conductivity and to identify the amount of contaminants collected therein, An antistatic device of a cyclone dust collector for a cyclone dust collector, characterized in that it comprises a humidifying means for discharging the humidified particles to the inside of the dust collecting chamber in which the dust collecting container is installed to make the dust collecting container highly humidified. The method of claim 1, The humidification means and the reservoir to store the water for humidification, An auxiliary water tank capable of receiving water of the water storage tank by a predetermined amount by a water supply adjusting member; An ultrasonic vibrator installed on a bottom surface of the auxiliary water tank so as to be operated in conjunction with the operation of the cyclone dust collector, and converting water inside the atomized state into an atomized state; An antistatic device of a cyclone dust collector for a cyclone dust collector, characterized in that it comprises a discharge port extending from the auxiliary water tank to the inside of the dust collecting chamber so as to discharge the atomized humidified particles into the dust collecting chamber. The method of claim 2, The reservoir is antistatic device of the cyclone dust collector for cyclone dust collector characterized in that it is formed of a transparent material to identify the amount of water contained therein. The method according to claim 1 or 2, The inside of the dust collecting chamber is provided with a humidity sensor for detecting the humidity therein and applying the detected signal to the driving control unit side to control the operation of the humidifying means according to the humidity state in the dust collecting chamber by the control of the driving control unit. Antistatic device of the dust collector for cyclone dust collector, characterized in that it is made to be.

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