KR20200047225A - Dust collecting sheet, dust collector for ambient particulate matter and the driving method thereof - Google Patents

Abstract

The present invention relates to an apparatus of collecting fine dust floating in the air using electrostatic force generated by means of frictional force, and more specifically, to an apparatus of, after power is supplied to a static electricity generation unit by means of rotational force of a motor, inducing the static electricity of a negative charge and the static electricity of a positive charge, simultaneously, and collecting fine dust floating in the air using an electrostatic plate charged with the negative charge (-) and the positive charge (+); and to an operation method thereof. In addition, the present invention relates to a dust collecting sheet which includes boron, nitrogen, aluminum components, thereby having improved physical and chemical adsorption power and also includes a silica gel or an activated carbon component, thereby providing moisture absorption power, and to a replacement method thereof.

Description

Fine dust collecting sheet, fine dust collecting device and its driving method {Dust collecting sheet, dust collector for ambient particulate matter and the driving method thereof}

The present invention relates to a device for collecting fine dust floating in the air by using the electrostatic force generated by the frictional force, and more specifically, after providing power to the static electricity generator by the rotational force of the motor, suspended in the air The present invention relates to a device for collecting fine dusts using an electrostatic plate charged with a negative charge (-) and a positive charge (+) and a driving method therefor. In addition, boron (Boron), nitrogen (nitrogen), aluminum (Aluminium) is included to improve physical adsorption and chemical adsorption, as well as silica gel (Silica-Gal) or activated carbon components are included, providing moisture absorption It relates to a fine dust using static electricity provided with a sheet therein and a driving method therefor.

Figure 1 is a view showing the size of the fine dust compared to the thickness of the hair.

Fine dust refers to particulate matter that is mainly scattered when burning chemical fuels such as turquoise, petroleum, or through exhaust gas from factories and automobiles. Fine dust is classified into fine dust (TD) for less than particle size (10 μm) and ultra fine dust (TTD) for less than particle size (2.5 μm), depending on the particle size. Considering that the diameter of the human hair (M) is a diameter (50-70 μm) as shown in FIG. 1, in the case of dust having a particle diameter (2.5 μm) or less classified as ultra fine dust (TTD), the human hair It can be seen that the size is considerably small enough to be (1/20 ~ 1/30) times of (M).

As such, the fine dust (TD) stays in the air because it is so small that it is invisible to the eye, and may penetrate the lungs or the like through the respiratory tract or move into the body along the blood vessels, thereby adversely affecting health.

In 2013, the International Agency for Research on Cancer (IARC) under the World Health Organization designated fine dust (TD) as a group 1 carcinogen identified as carcinogenic to humans. As it is widely known that fine dust (TD) and ultra fine dust (TTD) are harmful to the human body, the invention and demand for devices for collecting fine dust (TD) and ultra fine dust (TTD) are steadily increasing. .

FIG. 2 is a view showing the inside of a dust collecting device using static electricity previously registered by the applicant.

The fine dust collection technology using static electricity in FIG. 2 has an advantage of collecting even fine particles having a very small particle diameter (about 0.05 μm), and is one of the methods with high dust collection efficiency, while energy consumption is low. However, the electrostatic precipitator can only collect fine dust having a single polarity. In more detail, it is common that the polarity of the fine dust mainly has a negatively charged (-) polarity. However, when fine dust containing a component having a positive charge (+) polarity is present according to the heat of charge, a phenomenon in which fine dust is not absorbed by static electricity may occur, and thus there may be a variation in dust collection efficiency.

In addition, a dust collecting device using static electricity may have a variation in dust collection efficiency depending on water vapor that penetrates therein. This is due to the principle that the whole body is discharged by electron exchange with water vapor. The phenomenon in which static electricity does not occur in wet weather is one of the phenomena generated by this principle. Therefore, there is a need for an invention in which the efficiency of generating static electricity does not fluctuate depending on the degree of inflow of water vapor.

The present invention has been devised to solve the above problems, and a method for driving a dust collecting device and a method of driving the dust using static electricity that induces static electricity on the first and second static plates and collects the particles regardless of the polarity of the fine dust Want to provide.

In addition, after measuring the humidity inside the fine dust collecting device with a humidity sensor, by controlling the rotational speed of the motor in accordance with the humidity, the fine dust collecting device using static electricity to prevent the phenomenon of static electricity generation efficiency is reduced and its It is intended to provide a driving method.

In addition, by providing a dust detection sensor for measuring the dust collected on the fine dust collecting sheet, the replacement cycle information of the dust collecting sheet is transmitted to provide a fine dust collecting device using static electricity and a method for driving the same.

In addition, to provide a fine dust dust collecting device using static electricity that has improved adsorption power, including materials such as boron, nitrogen, and aluminum, which improve the adsorption power of fine dust, and a driving method thereof.

In addition, the present invention is to provide a fine dust dust collecting device using static electricity that improves hygroscopicity by including a material such as silica gel or activated carbon in a dust collecting device and a driving method thereof.

In addition, the present invention is intended to provide a fine dust collecting sheet and a method of replacing the same, which are designed to facilitate the replacement of the dust collecting sheet and improve convenience.

In order to achieve the above object, the present invention is a first electrostatic plate; A second electrostatic plate; At least one first static electricity generator; At least one second static electricity generator; And a static electricity induction wire connecting between the first static electricity plate and the first static electricity generating part and connecting between the second static electricity plate and the second static electricity generating part. It is intended to provide a device.

In addition, a power transmission shaft connected to the first static electricity generator and the second static electricity generator; It is intended to provide a fine dust collecting apparatus using static electricity, characterized in that it further comprises; a motor (motor) for transmitting a rotational force to the power transmission shaft.

In addition, the first static electricity generating unit is coupled to the power transmission shaft, the first rotating friction member rotating together; A first fixed friction member in close contact with the first rotating friction member; A first static electricity induction member installed spaced apart from the first rotating friction member and connected to the first static electricity plate through the static electricity induction wire; It is made, including, the second static electricity generating unit is coupled to the power transmission shaft second rotating friction member to rotate together; A second fixed friction member in close contact with the second rotating friction member; It is installed spaced apart from the second rotating friction member, and a second static electricity induction member connected to the second static electricity plate through the static electricity induction wire; to provide a fine dust collecting device using static electricity, characterized in that comprises a do.

In addition, the first rotational friction member is rotated in gear engagement with the power transmission shaft, and the first fixed friction member is in close contact with an outer circumferential surface on which the gear of the first rotational friction member is not formed. 2 The rotating friction member rotates in gear engagement with the power transmission shaft, and the second fixed friction member is in close contact with an outer circumferential surface on which the gear of the second rotating friction member is not formed, thereby collecting fine dust using static electricity. It is intended to provide a device.

In addition, the first rotational friction member is circular, and the second rotational friction member is intended to provide a fine dust collecting apparatus using static electricity, characterized in that it is circular.

In addition, the first static electricity induction member is formed in an arc shape and is provided at a position symmetric to the first fixed friction member, and the second static electricity induction member is formed in an arc shape and is provided at a position symmetrical to the second fixed friction member. It is intended to provide a fine dust collecting device using static electricity, characterized in that.

In addition, the first fixed friction member is in close contact with the first rotational friction member by the elastic force of the elastic member, and the second fixed friction member is in close contact with the second rotational friction member by the elastic force of the elastic member. It is intended to provide a fine dust collecting device using static electricity characterized by the above-mentioned.

In addition, the first rotational friction member and the first fixed friction member use different materials as the friction material, and the friction material of the first rotational friction member loses charge better than the friction material of the first fixed friction member and , The second rotating friction member and the second fixed friction member use different materials as the friction material, and the friction material of the second fixed friction member loses electric charges better than the friction material of the second rotating friction member. It is intended to provide a fine dust collecting device using static electricity characterized by the above-mentioned.

In addition, glass or plastic is used as the friction material of the first rotating friction member, Ebonite is used as the friction material of the first fixed friction member, and friction material of the second rotating friction member. It is intended to provide a fine dust collecting device using static electricity, characterized in that ebonite is used as the furnace, and glass or plastic is used as the friction material of the second fixed friction member.

In addition, the friction material of the first rotational friction member, the first fixed friction member, the second rotational friction member, or the second fixed friction member includes fur, ivory, woolen cloth, crystal, glass, silk, wood, It is intended to provide a fine dust collecting device using static electricity, characterized in that any one of cotton, rubber, plastic, metal, sulfur, celluloid, and ebonite is selected and used.

In addition, to provide a fine dust collecting apparatus using static electricity, characterized in that it further comprises; dust collecting sheet provided on the upper side of the first electrostatic plate and the second electrostatic plate.

In addition, the dust collecting sheet is to provide a fine dust collecting apparatus using static electricity, characterized in that any one of boron, nitrogen, aluminum, activated carbon is included.

In addition, the dust collecting sheet may include a first dust collecting region corresponding to the first electrostatic plate; A second dust collecting region corresponding to the second electrostatic plate; It is intended to provide a fine dust collecting device using static electricity, characterized in that comprises a; water absorption region provided between each of the first dust-collecting region and each of both ends of the dust collecting sheet.

In addition, to provide a fine dust collecting device using static electricity, characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

In addition, a humidity sensor (sensor); It is intended to provide a fine dust collecting device using static electricity, further comprising a control unit for adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor.

In addition, the control unit increases the rotation speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value, and decreases the rotation speed of the motor when the humidity value measured by the humidity sensor is less than a predetermined value. It is intended to provide a fine dust collecting apparatus using static electricity, characterized in that.

In addition, to provide a fine dust collecting device using static electricity, characterized in that it further comprises; a dust collection sensor for measuring the amount of dust collected in the dust collecting sheet.

In addition, the dust detection sensor is to provide a fine dust collecting device using static electricity, characterized in that the photo (photo) sensor or a differential pressure measurement sensor.

In addition, the present invention is a first dust collecting region; A second dust collection area; It is intended to provide a dust collecting sheet comprising; between the first dust collecting region and the second dust collecting region, and a water absorption region provided at both ends.

In addition, the first dust collecting region, the second dust collecting region or the moisture absorption region is to provide a dust collecting sheet characterized in that any one of boron, nitrogen, aluminum (aluminum), activated carbon is included.

In addition, it is intended to provide a dust collecting sheet characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

In addition, the present invention is the step of operating the motor; The power transmission shaft rotates together as the motor operates; Rotating the first rotational friction member of the one or more first static electricity generating units and the second rotational friction member of the one or more second static electricity generating units as the power transmission shaft rotates; Friction with the first fixed friction member as the first rotating friction member rotates and friction with the second fixed friction member as the second rotating friction member rotates; A step in which a first static electricity induction member is charged in the opposite polarity to the first rotating friction member, and a second static electricity induction member is charged in the opposite polarity to the second rotating friction member; The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. step; It is intended to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it comprises a.

In addition, a first static electricity plate connected to the first static electricity induction member and a second static electricity plate connected to the second static electricity induction member through a static electricity induction wire have opposite polarities to the first static electricity induction member and the second static electricity induction member, respectively. After the charging step, the control unit receives the humidity value measured by the humidity sensor; The control unit is based on the humidity value measured by the humidity sensor to control the rotational speed of the motor; to provide a method for driving a fine dust collecting apparatus using static electricity, further comprising.

In addition, the step of adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor by the control unit may increase the rotational speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value. And, if the humidity value measured by the humidity sensor is less than a predetermined value, the controller is to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it is achieved by reducing the rotational speed of the motor.

In addition, a first static electricity plate connected to the first static electricity induction member and a second static electricity plate connected to the second static electricity induction member through a static electricity induction wire have opposite polarities to the first static electricity induction member and the second static electricity induction member, respectively. After the charging step, the control unit receives a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor; Further comprising: when the measured value for the amount of dust collected on the dust collecting sheet corresponds to a predetermined replacement value, the control unit transmits information indicating that it is time for the dust collecting sheet to be replaced; An object of the present invention is to provide a method for driving a dust collector.

In addition, the present invention is the step of receiving a humidity value measured by the humidity sensor control unit; It is intended to provide a method for driving a fine dust collecting apparatus using static electricity, comprising the step of: controlling the rotation speed of the motor based on the humidity value measured by the humidity sensor.

In addition, the step of adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor by the control unit may increase the rotational speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value. And, if the humidity value measured by the humidity sensor is less than a predetermined value, the controller is to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it is achieved by reducing the rotational speed of the motor.

In addition, the present invention comprises the steps of receiving a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor by the control unit; When the measured value for the amount of dust collected on the dust collecting sheet corresponds to a preset replacement value, the control unit transmits information indicating that it is time to replace the dust collecting sheet. It is intended to provide a method of driving a used fine dust collector.

In addition, the first rotational friction member is engaged with the power transmission shaft and rotates, and the first fixed friction member is in close contact with an outer circumferential surface on which the gear of the first rotational friction member is not formed, and the second rotational friction is The member rotates in gear engagement with the power transmission shaft, and the second fixed friction member drives the fine dust collecting device using static electricity, characterized in that it is in close contact with an outer circumferential surface on which the gear of the second rotation friction member is not formed. I want to provide a method.

In addition, the first rotational friction member is circular, and the second rotational friction member is to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that it is circular.

In addition, the first static electricity induction member is formed in an arc shape and is provided at a position symmetric to the first fixed friction member, and the second static electricity induction member is formed in an arc shape and is provided at a position symmetrical to the first fixed friction member. It is intended to provide a method for driving a fine dust collecting device using static electricity, which is characterized by being.

In addition, the first fixed friction member is in close contact with the first rotating friction member by the elastic force of the elastic member, the second fixed friction member is in close contact with the second rotating friction member by the elastic force of the elastic member It is intended to provide a method for driving a fine dust collector using static electricity.

In addition, the first rotational friction member and the first fixed friction member use different materials as the friction material, and the friction material of the first rotational friction member loses charge better than the friction material of the first fixed friction member and , The second rotating friction member and the second fixed friction member use different materials as the friction material, and the friction material of the second fixed friction member loses electric charges better than the friction material of the second rotating friction member. It is intended to provide a method for driving a fine dust collecting device using static electricity, which is characterized by the above-mentioned.

In addition, glass or plastic is used as the friction material of the first rotating friction member, Ebonite is used as the friction material of the first fixed friction member, and friction material of the second rotating friction member. It is intended to provide a method for driving a fine dust collecting apparatus using static electricity, wherein ebonite is used as the furnace, and glass or plastic is used as the friction material of the second fixed friction member.

In addition, the friction material of the first rotational friction member, the first fixed friction member, the second rotational friction member, or the second fixed friction member includes fur, ivory, woolen cloth, crystal, glass, silk, wood, It is intended to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that any one of cotton, rubber, plastic, metal, sulfur, celluloid, and ebonite is selected and used.

In addition, to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that any one of boron, nitrogen, aluminum, and activated carbon is included in the dust collecting sheet.

In addition, the dust collecting sheet may include a first dust collecting region corresponding to the first electrostatic plate; A second dust collecting region corresponding to the second electrostatic plate; It comprises a; water absorption region provided between each of the both ends of the dust collecting sheet and the first dust collecting region and the second dust collecting region; characterized in that the moisture absorption region contains a silica gel or activated carbon component To provide a method for driving a fine dust collecting device using static electricity.

In addition, the dust detection sensor is to provide a method of driving a fine dust collecting device using static electricity, characterized in that the photo sensor or differential pressure measurement sensor.

In addition, the present invention is a fine dust suction module (module); The fine dust removal module provided at the rear end of the fine dust suction unit; is configured to include, the fine dust suction module is a mesh (mesh) network provided at the entrance of the fine dust suction module; A fan provided at a rear end of the mesh network; An ultrasonic generator provided at the rear end of the fan; It is configured to include, The fine dust removing module is a first electrostatic plate; a second electrostatic plate; At least one first static electricity generator; At least one second static electricity generating unit; an electrostatic induction wire connecting the first static electricity plate and the first static electricity generating unit, and connecting the second static electricity plate and the second static electricity generating unit; It is intended to provide a fine dust collecting device using static electricity, characterized in that comprises a.

In addition, the fine dust removing module further comprises a dust collecting sheet, and the dust collecting sheet includes a filter area corresponding to an inlet of the fine dust removing module; A first dust collecting region corresponding to the first electrostatic plate; And a second dust collecting region corresponding to the second static electricity plate. The first dust collecting region covers all of the upper side of the first static electricity plate, and the second dust collecting region is a second static electricity plate. It is intended to provide a fine dust collecting apparatus using static electricity, which covers all of the upper side of the filter area, so that the filter area covers all the inlets of the fine dust removal module.

In addition, the dust collecting sheet is at both ends of the dust collecting sheet, between the first dust collecting region and the second dust collecting region, the water absorption region provided between the filter region and the first dust collecting region; It is intended to provide a fine dust collecting device using static electricity, characterized in that made.

In addition, the fine dust suction module is to provide a fine dust collecting apparatus using static electricity, characterized in that further comprises a; heating member provided at the rear end of the mesh network.

In addition, the fine dust removing module includes a power transmission shaft connected to the first static electricity generating part and the second static electricity generating part; A motor that transmits rotational force to the power transmission shaft; To provide a fine dust collecting apparatus using static electricity, characterized in that it further comprises a.

In addition, the first static electricity generating unit is coupled to the power transmission shaft, the first rotating friction member rotating together; A first fixed friction member in close contact with the first rotating friction member; A first static electricity induction member installed spaced apart from the first rotating friction member and connected to the first static electricity plate through the static electricity induction wire; It is made, including, the second static electricity generating unit is coupled to the power transmission shaft second rotating friction member to rotate together; A second fixed friction member in close contact with the second rotating friction member; A second static electricity induction member installed spaced apart from the second rotating friction member and connected to the second static electricity plate through the static electricity induction wire; It is intended to provide a fine dust collecting device using static electricity, characterized in that comprises a

In addition, the first rotational friction member is rotated by being coupled to the power transmission shaft and gear, and the first fixed friction member is in close contact with an outer circumferential surface on which the gear of the first rotational friction member is not formed,

The second rotating friction member rotates in gear engagement with the power transmission shaft, and the second fixed friction member is in close contact with an outer circumferential surface on which the gear of the second rotating friction member is not formed. It is intended to provide a dust collecting device.

In addition, the first rotational friction member is circular, and the second rotational friction member is to provide a fine dust collecting device using static electricity, characterized in that the circular.

In addition, the first corrector induction member is formed in an arc shape and is provided at a position symmetric to the first fixed friction member, and the second static electricity induction member is formed in an arc shape and is positioned at a position symmetrical to the second fixed friction member. It is intended to provide a fine dust collecting device using static electricity, characterized in that provided.

In addition, the first fixed friction member is in close contact with the first rotational friction member by the elastic force of the elastic member, and the second fixed friction member is in close contact with the second rotational friction member by the elastic force of the elastic member. It is intended to provide a fine dust collecting device using static electricity characterized by the above-mentioned.

In addition, the first rotational friction member and the first fixed friction member use different materials as the friction material, and the friction material of the first rotational friction member loses charge better than the friction material of the first fixed friction member and , The second rotating friction member and the second fixed friction member use different materials as the friction material, and the friction material of the second fixed friction member loses electric charges better than the friction material of the second rotating friction member. It is intended to provide a fine dust collecting device using static electricity characterized by the above-mentioned.

In addition, the fine dust removal module is a humidity sensor (sensor); A control unit for adjusting the rotation speed of the motor based on the humidity value measured by the humidity sensor; It is intended to provide a fine dust collecting device using static electricity, characterized in that further comprises a.

In addition, the control unit increases the rotation speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value, and decreases the rotation speed of the motor when the humidity value measured by the humidity sensor is less than a predetermined value. It is intended to provide a fine dust collecting apparatus using static electricity, characterized in that.

In addition, the fine dust removal module is to provide a dust collecting device using static electricity, characterized in that it further comprises a dust collection sensor for measuring the amount of dust collected in the dust collecting sheet.

In addition, the present invention is a filter region; A first dust collection area; A second dust collection area; It is intended to provide a dust collecting sheet comprising; between the filter region and the first dust collecting region, between the first dust collecting region and the second dust collecting region, and a water absorption region provided at both ends.

In addition, the present invention includes the steps of operating the fan; A step of operating the ultrasonic generator; A step in which the motor operates; The power transmission shaft rotates together as the motor operates; Rotating the first rotational friction member of the one or more first static electricity generating units and the second rotational friction member of the one or more second static electricity generating units as the power transmission shaft rotates; Friction with the first fixed friction member as the first rotating friction member rotates and friction with the second fixed friction member as the second rotating friction member rotates; A step in which a first static electricity induction member is charged in the opposite polarity to the first rotating friction member, and a second static electricity induction member is charged in the opposite polarity to the second rotating friction member; The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. step; It is intended to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it comprises a.

In addition, after the step of operating the fan, the air sucked into the fine dust suction module through the heating member is heated; Passing air through the fan through a cyclone unit; It is intended to provide a method of driving a fine dust collecting apparatus using static electricity, further comprising a.

In addition, after the operation of the ultrasonic generator, the air sucked into the fine dust suction module passes through the outlet of the fine dust suction module manufactured in the form of a Venturi tube and flows into the fine dust removal module through the filter area of the dust collecting sheet. step; It is intended to provide a method of driving a fine dust collecting device using static electricity, characterized in that is further included.

In addition, a first static electricity plate connected to the first static electricity induction member and a second static electricity plate connected to the second static electricity induction member through a static electricity induction wire have opposite polarities to the first static electricity induction member and the second static electricity induction member, respectively. After the charging step, the control unit receives the humidity value measured by the humidity sensor; Adjusting, by the control unit, the rotation speed of the motor based on the humidity value measured by the humidity sensor; It is intended to provide a method of driving a fine dust collecting apparatus using static electricity, further comprising a.

In addition, the step of adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor by the control unit may increase the rotational speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value. And, if the humidity value measured by the humidity sensor is less than a predetermined value, the controller is to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it is achieved by reducing the rotational speed of the motor.

In addition, a first static electricity plate connected to the first static electricity induction member and a second static electricity plate connected to the second static electricity induction member through a static electricity induction wire have opposite polarities to the first static electricity induction member and the second static electricity induction member, respectively. After the charging step, the control unit receives a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor; Further comprising: when the measured value for the amount of dust collected on the dust collecting sheet corresponds to a predetermined replacement value, the control unit transmits information indicating that it is time for the dust collecting sheet to be replaced; An object of the present invention is to provide a method for driving a dust collector.

In addition, the present invention is the step of receiving a humidity value measured by the humidity sensor control unit;

It is intended to provide a method for driving a fine dust collecting apparatus using static electricity, comprising the step of: controlling the rotation speed of the motor based on the humidity value measured by the humidity sensor.

In addition, the step of adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor by the control unit may increase the rotational speed of the motor when the humidity value measured by the humidity sensor is greater than or equal to a preset value. And, if the humidity value measured by the humidity sensor is less than a predetermined value, the controller is to provide a method of driving a fine dust collecting apparatus using static electricity, characterized in that it is achieved by reducing the rotational speed of the motor.

In addition, the present invention comprises the steps of receiving a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor by the control unit; When the measured value for the amount of dust collected on the dust collecting sheet corresponds to a preset replacement value, the control unit transmits information indicating that it is time to replace the dust collecting sheet. It is intended to provide a method of driving a used fine dust collector.

In addition, the first rotational friction member is rotated in gear engagement with the power transmission shaft, and the first fixed friction member is in close contact with an outer circumferential surface where the gear of the first rotational friction member is not formed, and the second rotational friction is achieved. The member rotates in gear engagement with the power transmission shaft, and the second fixed friction member is driven in close contact with an outer circumferential surface on which the gear of the second rotation friction member is not formed. I want to provide a method.

In addition, the first rotational friction member is circular, and the second rotational friction member is to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that it is circular.

In addition, the first static electricity induction member is formed in an arc shape and is provided at a position symmetric to the first fixed friction member, and the second static electricity induction member is formed in an arc shape and is provided at a position symmetrical to the first fixed friction member. It is intended to provide a method for driving a fine dust collecting device using static electricity, which is characterized by being.

In addition, the first fixed friction member is in close contact with the first rotational friction member by the elastic force of the elastic member, and the second fixed friction member is in close contact with the second rotational friction member by the elastic force of the elastic member. It is intended to provide a method for driving a fine dust collecting device using static electricity, which is characterized by the above-mentioned.

In addition, the first rotational friction member and the first fixed friction member use different materials as the friction material, and the friction material of the first rotational friction member loses charge better than the friction material of the first fixed friction member and , The second rotating friction member and the second fixed friction member use different materials as the friction material, and the friction material of the second fixed friction member loses electric charges better than the friction material of the second rotating friction member. It is intended to provide a method for driving a fine dust collecting device using static electricity, which is characterized by the above-mentioned.

In addition, the dust collecting sheet is a filter area corresponding to the inlet of the fine dust removal module; A first dust collecting region corresponding to the first electrostatic plate; A second dust collecting region corresponding to the second electrostatic plate; A water absorption region provided between each of the both ends of the dust collecting sheet, between the filter region and the first dust collecting region, and between the first dust collecting region and the second dust collecting region; It is made to include, and to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

In addition, the present invention is a fine dust suction module (module); A fine dust removal module provided at a rear end of the fine dust suction unit; It is configured to include, the fine dust suction module is a mesh (mesh) provided at the entrance of the fine dust suction module; A fan provided at a rear end of the mesh network; An ultrasonic generator provided at the rear end of the fan; It is configured to include, the fine dust removal module is a first electrostatic plate; A second electrostatic plate; At least one first static electricity generator; At least one second static electricity generator; An electrostatic induction wire connecting the first static electricity plate and the first static electricity generating part and connecting between the second static electricity plate and the second static electricity generating part; and a dust collecting sheet. The dust collecting sheet includes a filter area corresponding to an inlet of the fine dust removal module; A first dust collecting region corresponding to the first electrostatic plate; A second dust collecting region corresponding to the second electrostatic plate; Each of both ends of the dust collecting sheet, between the first dust collecting region and the second dust collecting region, the water absorption region provided between the filter region and the first dust collecting region; is made, including, the first dust collection The area covers all of the upper side of the first electrostatic plate, and the second dust collection area covers all of the upper side of the second electrostatic plate, so that the filter area covers all the inlets of the fine dust removal module, It is intended to provide a fine dust collecting apparatus using static electricity, characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

In addition, the dust collecting sheet is to provide a fine dust collecting apparatus using static electricity, characterized in that any one of boron, nitrogen, aluminum (aluminum), activated carbon is included.

In addition, the fine dust suction module is to provide a fine dust collecting apparatus using static electricity, characterized in that further comprises a; heating member provided at the rear end of the mesh network.

In addition, the heating member is to provide a fine dust collecting device using static electricity, characterized in that the thermoelectric element.

In addition, the fine dust suction module is to provide a fine dust collecting apparatus using static electricity, characterized in that further comprises a cyclone (cyclone) portion provided at the rear end of the fan.

In addition, the outlet of the fine dust suction module is to provide a fine dust collecting device using static electricity, characterized in that formed in the form of a venturi (venturi) tube.

In addition, the first static electricity generating unit is coupled to the power transmission shaft, the first rotating friction member rotating together; A first fixed friction member in close contact with the first rotating friction member; A first static electricity induction member installed spaced apart from the first rotating friction member and connected to the first static electricity plate through the static electricity induction wire; It is made, including, the second static electricity generating unit is coupled to the power transmission shaft second rotating friction member to rotate together; A second fixed friction member in close contact with the second rotating friction member; A second static electricity induction member installed spaced apart from the second rotating friction member and connected to the second static electricity plate through the static electricity induction wire; It is intended to provide a fine dust collecting apparatus using static electricity, characterized in that comprises a.

In addition, glass or plastic is used as the friction material of the first rotating friction member, Ebonite is used as the friction material of the first fixed friction member, and friction material of the second rotating friction member. It is intended to provide a fine dust collecting device using static electricity, characterized in that ebonite is used as the furnace, and glass or plastic is used as the friction material of the second fixed friction member.

In addition, the friction material of the first rotational friction member, the first fixed friction member, the second rotational friction member, or the second fixed friction member includes fur, ivory, woolen cloth, crystal, glass, silk, wood, It is intended to provide a fine dust collecting device using static electricity, characterized in that any one of cotton, rubber, plastic, metal, sulfur, celluloid, and ebonite is selected and used.

In addition, the fine dust removal module is to provide a dust collecting device using static electricity, characterized in that it further comprises a dust collection sensor for measuring the amount of dust collected in the dust collecting sheet.

In addition, the dust detection sensor is to provide a fine dust collecting device using static electricity, characterized in that the photo (photo) sensor or a differential pressure measurement sensor.

In addition, the present invention is a filter region; A first dust collection area; A second dust collection area; A water absorption region provided between the filter region and the first dust collecting region, between the first dust collecting region and the second dust collecting region, and at both ends; Including,

It is intended to provide a dust collecting sheet comprising any one of boron, nitrogen, aluminum, and activated carbon in the filter area, the first dust collection area, the second dust collection area, or the water absorption area.

In addition, it is intended to provide a dust collecting sheet characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

In addition, the present invention includes the steps of operating the fan; Step of operating the ultrasonic generator; Step of operating the motor; The power transmission shaft rotates together as the motor operates; Rotating the first rotational friction member of the one or more first static electricity generating units and the second rotational friction member of the one or more second static electricity generating units as the power transmission shaft rotates; Friction with the first fixed friction member as the first rotating friction member rotates and friction with the second fixed friction member as the second rotating friction member rotates; A step in which a first static electricity induction member is charged in the opposite polarity to the first rotating friction member, and a second static electricity induction member is charged in the opposite polarity to the second rotating friction member; The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. step; It includes, glass or plastic (plastic) is used as the friction material of the first rotating friction member, ebonite (Ebonite) is used as the friction material of the first fixed friction member, and the second rotating friction member Ebonite is used as the friction material, and the friction material of the second fixed friction member is glass or plastic.

In addition, the friction material of the first rotational friction member, the first fixed friction member, the second rotational friction member, or the second fixed friction member includes fur, ivory, woolen cloth, crystal, glass, silk, wood, It is intended to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that any one of cotton, rubber, plastic, metal, sulfur, celluloid, and ebonite is selected and used.

In addition, a first static electricity plate connected to the first static electricity induction member and a second static electricity plate connected to the second static electricity induction member through a static electricity induction wire have opposite polarities to the first static electricity induction member and the second static electricity induction member, respectively. After the charging step, the control unit receives a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor; In addition, when the measured value for the amount of dust collected on the dust collecting sheet corresponds to a preset replacement value, the control unit transmits information indicating that it is time to replace the dust collecting sheet; and further comprising the dust collecting sheet It is intended to provide a method for driving a fine dust collecting device using static electricity, characterized in that any one of boron, nitrogen, aluminum, and activated carbon is included.

In addition, the present invention comprises the steps of receiving a measurement value for the amount of dust collected in the dust collecting sheet from the dust collecting sensor by the control unit; And when the measured value for the amount of dust collected on the dust collecting sheet corresponds to a preset replacement value, the control unit sending out information indicating that it is time to replace the dust collecting sheet; including, boron in the dust collecting sheet , Nitrogen, aluminum, to provide a method for driving a fine dust collecting apparatus using static electricity, characterized in that any one of activated carbon is included.

In addition, the present invention is to provide a method for driving a fine dust collecting device using static electricity, wherein the dust detection sensor is a photo sensor or a differential pressure measurement sensor.

According to the present invention, the fine dust collecting device using static electricity and a driving method thereof, the fine dust collecting sheet and a replacement method thereof have the following effects.

First, it is possible to collect both fine dust having a negative charge (-) polarity and fine dust having a positive charge (+) polarity, thereby improving the dust collection efficiency of the fine dust.

Second, there is an effect of controlling the rotational speed of the motor according to humidity to prevent the static electricity generation efficiency from being lowered.

Third, by predicting the replacement cycle of the dust collecting sheet using the dust collection sensor, it is possible to easily perform the replacement operation, thereby improving convenience.

Fourth, by including materials such as boron, aluminum, nitrogen, and activated carbon in the dust collecting sheet, there is an effect capable of improving physical and chemical adsorption power of fine dust.

Fifth, a portion of the dust collecting sheet is provided with a silica gel or an activated carbon component to remove moisture to maintain a constant electrostatic force generated in the static electricity generating unit.

Sixth, after providing the replacement cycle information of the dust collecting sheet, a detachable dust collecting sheet is provided to facilitate replacement and repair of the dust collecting sheet, thereby providing convenience.

Seventh, the fine dust intake module including a mesh (mesh) network in which the fine dust flows first is provided by an absorbent containing any one or more components of silica gel, super absorbent polymer, volcanic stone, activated carbon, to further dissolve inside the device. It has the effect of preventing mold formation.

Eighth, the fine dust is aggregated with each other by the ultrasonic module, thereby increasing the volume, thereby improving the dust collection efficiency.

Ninth, after the heating member evaporates the water vapor flowing together with the fine dust by heating the air, there is an effect that can prevent the charge of the whole charge due to water vapor to improve the dust collection efficiency.

Tenth, the fine dust is filtered according to the volume by the cyclone unit, thereby providing the efficiency of fine dust collection.

Figure 1 is a view showing the size of the fine dust compared to the thickness of the hair.
2 is a view showing a perspective view of a dust collecting device using static electricity, which is a conventional invention.
3 is a view showing a fine dust collecting device using the principle of corona discharge.
4 is a view showing a state of the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.
5 is a view showing the configuration of a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
6 is a view showing the state of the first rotating friction member and the first fixed friction member of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
7 is a view showing the detailed configuration of the first fixed friction member of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
8 is an enlarged view showing a detailed configuration of the static electricity generating unit and the static electricity plate.
9 is a view showing a state in which fine dust having a positive charge polarity and fine dust having a negative charge polarity are collected.
10 is a view showing a state in which materials that lose electric charge when rubbing an object are arranged in order.
11 is a view showing a state of the dust collecting sheet according to a preferred embodiment of the present invention.
12 is a view showing a method of replacing the dust collecting sheet of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
13 is a view showing a state of a humidity sensor additionally provided in a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
14 is a view showing a state of the dust detection sensor of the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.
15 is a view showing a state in which a fine dust suction module is added to a fine dust collecting device using static electricity according to a preferred embodiment of the present invention.
16 is a view showing a state in which a modified form of the fine dust suction module is added to the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.
17 is a view showing a driving sequence of a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.
18 is a view showing a sequence in which the rotational speed of the motor is adjusted according to a preferred embodiment of the present invention.
19 is a view showing an order in which the replacement time of the dust collecting sheet is determined according to a preferred embodiment of the present invention.
20 is a view showing a driving sequence of a fine dust collecting device using static electricity when a fine dust suction module is mounted according to a preferred embodiment of the present invention.
21 is a view showing a driving sequence of a fine dust collecting apparatus using static electricity according to another embodiment of the present invention equipped with a fine dust suction module according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention can be variously changed and can have various forms, and specific embodiments are illustrated in the drawings and are described in detail in the text. However, this is not intended to limit the present invention to a specific disclosure form, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present invention are included.

In addition, in the description of the present invention, terms such as “first” and “second” are used only for the purpose of distinguishing one component from other components, and are not used to limit any meaning. And, unless the context clearly indicates otherwise, a singular expression includes a plural expression, and terms such as “comprise” or “have” include features, numbers, steps, operations, components, parts, or parts described in the specification. It is to be understood that a combination of these is intended to indicate the existence, and does not preclude the existence or addition possibility of one or more other features or numbers, steps, operations, components, parts or combinations thereof.

3 is a view showing a fine dust collecting device using the principle of corona discharge.

In the case of the conventional fine dust apparatus 10 using static electricity registered by the present applicant, there is a possibility that fine dust having a specific charge that is not a structure that is collected regardless of the polarity of the fine dust may not be collected. Corona Discharge technology has been used to compensate for this disadvantage. The fine dust collecting device 30 using corona discharge is a method of collecting fine dust after artificially applying polarity to the fine dust through corona discharge.

However, the corona discharge method has a drawback that power loss occurs when a high voltage is applied, and has the disadvantage that it reacts with atmospheric particles to generate an ozone compound, which can be detrimental to human health. Accordingly, the present invention is intended to complement the conventional fine dust apparatus 10 using static electricity registered by the applicant and to invent a fine dust collecting apparatus that can be safely used.

4 is a view showing a state of the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.

 The fine dust collecting apparatus 100 using static electricity according to the present invention may be implemented in various ways, such as 1 in FIG. (A) or 2 in FIG. (A), and may be configured in a configuration not limited to the size of the exterior. . Therefore, it can be used for the same purpose as the auxiliary device of the air cleaning device, and can also be used as an independent dust collecting device.

Accordingly, it may be implemented in a form attached to the interior of the vehicle as shown in the drawing (B).

5 is a view showing the configuration of a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

The fine dust collecting apparatus 100 using static electricity according to a preferred embodiment of the present invention may be configured to include one or more first static electricity generators 200 and one or more second static electricity generators 300. The first static electricity generating unit 200 may include a first rotating friction member 250, a first fixed friction member 260, and a first static electricity induction member 270. In addition, the second static electricity generating unit 300 may include a second rotating friction member 350, a second fixed friction member 360, and a second static electricity induction member 370. In addition, the dust collecting sheet 170 may be made of a further provided configuration. Since these components are configured to remove fine dust, they may also be referred to as a fine dust removal module 100a. In addition, a fine dust suction module 100b made of a configuration for suctioning fine dust may be included to be achieved.

As shown in FIG. 5, the first static electricity generating part 200 and the second static electricity generating part 300 may be configured to be provided with one or more. If one or more of the first static electricity generating part 200 and the second static electricity generating part 300 are provided, they may be provided without limiting a specific number. In addition to this, the fine dust collecting apparatus 100 using static electricity may also be provided with a first static plate 184 and a second static plate 185 at the bottom of the dust collecting sheet 170.

In addition, the first static electricity generating part 200, the second static electricity generating part 300 further includes a power transmission shaft 430 providing friction power, and a motor 400 providing rotational force to the power transmission shaft 430 Can be done by

The first rotational friction member 250 may be coupled to a power transmission shaft 430 and a gear. Therefore, when the power transmission shaft 430 is rotated, the rotational force of the power transmission shaft 430 is transmitted to the first rotational friction member 250 to be configured to generate static electricity with the first fixed friction member 260. . Likewise, the second static electricity generating part 300 is also coupled to the first static electricity generating part 200 and the second rotating friction member 350 by a power transmission shaft 430 and a gear, so that the second fixed friction member 360 ) And static electricity generating components. However, the first static electricity generator 200 may induce static electricity so that the first static electricity plate 184 is positively charged (+), and the second static electricity generator 300 has a second static electricity plate 185. The difference is that they can be charged with negative charges (-).

Therefore, the fine dust collecting apparatus 100 using static electricity according to a preferred embodiment of the present invention, the first static electricity plate 184 charged with negative charge and the second static electricity plate 185 with positive charge to collect fine dust All of them are provided, so you can expect the effect of collecting dust regardless of the polarity of fine dust.

6 is a view showing the state of the first rotating friction member and the first fixed friction member of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

6, the first rotating friction member 250 and the first fixed friction member 260 will be described in more detail. It can be seen that the first rotational friction member 250 of the first static electricity generating unit 200 is configured to rotate in combination with the power transmission shaft 430 in the form of a gear. On the other hand, the first fixed friction member 260 may be configured to be in close contact with an outer circumferential surface on which the gear of the first rotational friction member 250 is not formed. Accordingly, it can be seen that the first rotational friction member 250 rotates by the rotational force transmitted from the power transmission shaft 430 and rubs with the first fixed friction member 260. Accordingly, the first rotating friction member 250 is rubbed with the first fixed friction member 260, and electric charges are charged to induce static electricity. The configuration and operation of the second rotating friction member 350 and the second fixed friction member 360 are the same.

7 is a view showing the detailed configuration of the first fixed friction member of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

For the preferred description of the present invention will be described by dividing the drawing of FIG. 7 into (A) and (B). The first fixed friction member 260 may be formed by including a first elastic member 265 therein. The first elastic member 265 may be made of a first elastic spring 265a and a first friction pad 265b as shown in the drawing (A). It can be made of one friction brush (265c). However, the first elastic member 265 is not limited to the shape of the first elastic spring 265a, the first friction pad 265b, and the first friction brush 265c.

It can be seen that the first fixed friction member 260 has a structure in close contact with the first rotational friction member 250 by the first elastic member 265. The detailed configuration of the second fixed friction member 360 and the second elastic member 365 may be configured in the same manner.

8 is an enlarged view showing a detailed configuration of the static electricity generating unit and the static electricity plate.

It can be seen that the first electrostatic induction member 270 according to the present invention is spaced apart from the first rotational friction member 250. In addition, it can be seen that the first static electricity induction member 270 is connected to the first static electricity plate 184 along the static electricity induction line 500.

In FIG. 8, the electrostatic induction wire 500 connecting between the first electrostatic plate 184 and the first electrostatic induction member 270 is shown as (500-1) and (500-2), and the second electrostatic plate It can be seen that the electrostatic induction wires 500 connecting between the 185 and the second electrostatic induction member 370 are represented by (500-3) and (500-4). Previously, it was described that the number of the first static electricity generating unit 200 and the second static electricity generating unit 300 is not limited if one or more are satisfied. Therefore, if one or more of the electrostatic induction wires 500 are satisfied, the number may not be limited.

After the first rotational friction member 250 according to the present invention is rubbed with the first fixed friction member 260, the first static friction member 270 may be configured to be charged according to the static electricity induction phenomenon. . If the first rotational friction member 250 is charged with the positive electrode (+), the first static electricity induction member 270 that is close to the first rotational friction member 250 may be charged with the negative electrode (-). On the other hand, it can be seen that the first electrostatic plate 184 electrically connected to the first electrostatic induction member 270 is charged with the same charge as the first rotational friction member 250, that is, the positive electrode (+). Therefore, the first rotating friction member 250 may induce the first electrostatic plate 270 to be charged with the positive electrode, and the second rotating friction member 350 may induce the second electrostatic plate 185 to be charged with the negative electrode. You can see that you can.

9 is a view showing a state in which fine dust having a positive charge polarity and fine dust having a negative charge polarity are collected.

For the preferred description of the present invention according to the drawings, the fine dust having a negative charge (-) polarity (D1) and the fine dust having a positive charge (+) polarity will be represented as (D2). According to the foregoing description, the first electrostatic plate 184 charged with the polarity of the positive charge by the electrostatic induction phenomenon may collect fine dust D1 having the polarity of the negative charge, and the second electrostatic plate charged with the polarity of the negative charge. (185) can collect fine dust (D2) having a positive charge polarity. Therefore, the dust collecting apparatus 100 using static electricity according to the present invention can expect an effect capable of collecting dust regardless of the polarity of the fine dust.

10 is a view showing a state in which materials that lose electric charge when rubbing an object are arranged in order.

According to FIG. 10, materials that are easily charged with positive charges, that is, materials that lose charge well, are arranged in order, from fur to ebonate. The first static electricity generating part 200 and the second static electricity generating part 300 according to a preferred embodiment of the present invention may be made of materials shown in FIG. 10.

However, a material that loses electric charges more easily (ie, is more likely to be positively charged) than the first fixed friction member 260 may be used as the first rotational friction member 250 to smoothly generate friction. On the other hand, the second fixed friction member 360 may use a material that loses electric charge better than the second rotating friction member 350.

For example, when ebonite, a material that is easily charged with a negative charge (-), is used in the first fixed friction member 260, the first rotating friction member 250 has a property of losing electric charges better than ebonite. Glass (plastic) having excitation (ie, having a property of being relatively positively charged (+) and easily charged) may be used. Accordingly, the first fixed friction member 260 is charged with a negative charge (-), and the first rotating friction member 250 can be charged with a positive charge (+).

On the other hand, when the second rotational friction member 350 is used as a material that is easily charged with a negative charge (-), ebonite, the second fixed friction member 260b loses charge better than ebonite (i.e., positive charge (+ ), Glass and plastic (which are easy to charge) can be used. Therefore, the second fixed friction member 360 is charged with a positive charge (+), and the second rotating friction member 350 can be charged with a negative charge (-).

As a result, the first static electricity plate connected to the first static electricity induction part 200 may be charged with the positive electrode (+), and the second static electricity plate connected to the second static electricity induction part 300 may be charged with the negative electrode (-). .

11 is a view showing a state of the dust collecting sheet in a preferred embodiment of the present invention.

The dust collecting sheet 170 according to the present invention may be formed in a form installed on the first electrostatic plate 184 and the second electrostatic plate 185.

The dust collecting sheet 170 may be divided into a first dust collection area 171, a second dust collection area 172, and a moisture absorption area 173. In particular, the water absorption region 173 does not refer to one specific region, and may be divided into sections (173a), (173b), (173c), and (173d) as shown in FIG. 11. The sections (173a), (173b), (173c), and (173d) are sections arbitrarily referred to for a preferred description of the present invention and may not be referred to as regular sections. In addition, the dust collecting sheet 170 may be configured with a filter region 174 added.

The dust collecting sheet 170 may include any one of boron, nitrogen, aluminum, and activated carbon.

The dust-collecting sheet 170 containing boron and nitrogen additives may have improved physical adsorption power to fine dust, and the dust-collecting sheet 170 containing aluminum additives may have improved chemical adsorption power to fine dust to collect dust sheet 170 The fine dust adsorption power of can be improved.

The moisture absorption region 173 may include silica gel or activated carbon components. Silica gel is a strong net structured silicic acid particle produced by the reaction of sulfuric acid and sodium silicate, and has a very large surface area, so it has a very good ability to absorb water or alcohol, and is widely used as a dehumidifier. In addition, activated carbon not only has an excellent ability to remove moisture from the air, but also has an excellent ability to remove odors and bacteria.

The moisture absorption region 173 of the dust collecting sheet 170 according to the present invention contains silica gel or an activated carbon component to absorb moisture, prevents deterioration of static electricity generation ability due to moisture and rust caused by moisture It has the effect of preventing prevention. For reference, when the activated carbon component is selected as the water removal agent, it is not necessarily provided only in the water absorption region 173, and may be designed to be evenly included over the entire surface of the dust collecting sheet 170.

12 is a view showing a method of replacing the dust collecting sheet of the fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

For a preferred description of the present invention, a drawing in which a dust collecting sheet 170 includes a first dust collecting region 171, a second dust collecting region 172, and a moisture absorbing region 170 (A), the dust collecting sheet 170 The drawing including the filter region in FIG. 2 will be described as (B). It is designed to replace the fine dust in the dust collecting sheet 170 according to a preferred embodiment of the present invention when it is collected with a predetermined mass and capacity or higher. In the drawing (A) including the first dust collecting region 171, the second dust collecting region 172, and the water absorption region 170 in the dust collecting sheet 170, fine using static electricity in the form of the dust collecting sheet 170 It can be inserted into the dust collecting device 100, but in the case of the drawing (B) in which the filter area 174 is included in the dust collecting sheet 170, after the step (1) of inserting the dust collecting sheet 170, fine dust It may be mounted as a step (2) of closing the suction module (100b). When the fine dust suction module 100b is closed, the filter region 174 of the dust collecting sheet 170 can naturally act as a physical filter.

Therefore, the user can freely replace the dust collecting sheet 170 to smoothly carry out the cleaning and repair work of the dust collecting sheet 170, which can be viewed as an improved outbreak of convenience.

13 is a view showing a state of a humidity sensor additionally provided in a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

This is to prevent the inefficiency due to the principle that the whole is discharged by the electronic exchange with water vapor. The dust collecting device 100 using static electricity according to the present invention is equipped with a humidity sensor 750 inside and measures humidity. , Measurement information may be transmitted to the control unit 700. The control unit 700 receiving the humidity measurement information from the humidity sensor 750 may increase the rotation speed of the motor 400 when the value measured by the humidity sensor 750 is greater than or equal to a preset value.

After the rotational speed of the motor 400 increases, the rotational speeds of the first rotational friction member 250 and the second rotational friction member 350 increase, so that the first rotational friction member 250 and the first fixed friction member The frictional force generated by 260 may be increased, and the frictional force generated by the second rotating friction member 350 and the second fixed friction member 360 may also be increased. Therefore, the electrostatic force induced on the first electrostatic plate 184 and the second electrostatic plate 185 is increased, so that the electrostatic force is reduced even when the humidity is increased. Conversely, when the value measured by the humidity sensor 750 is equal to or less than a preset value, the control unit 700 may reduce the rotation speed of the motor 400. Therefore, the fine dust collecting apparatus 100 using static electricity according to a preferred embodiment of the present invention can be expected to have an effect of preventing the phenomenon that the static electricity generation efficiency is lowered and the dust collection efficiency is lowered as the humidity increases.

14 is a view showing a state of the dust detection sensor of the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.

The dust collection sensor 770 according to a preferred embodiment of the present invention may include a differential pressure measurement sensor 774 and a photo sensor, which are methods for measuring the differential pressure inside and outside the dust collecting sheet 170. . After the dust collection sensor 800 measures the amount of fine dust collected in the dust collecting sheet 170, the measured information may be received by the control unit 700. The control unit 750 receiving the information of the fine dust collected on the dust collecting sheet 170 may inform the user of the replacement cycle of the dust collecting sheet 170 according to the preset amount of fine dust.

Therefore, it can be seen that the dust collection sensor 770 has an effect of determining the replacement cycle by measuring the degree of fine dust collected on the dust collection sheet 170. The dust collection sensor 770 is the end of the first dust collection area 171 and the second dust collection area 172, or the dust collection sensor 770 is located between the first dust collection area 171 and the second dust collection area 172. It can be installed and arranged to accurately detect the degree of dust collection. In addition, if the dust collection amount of fine dust can be accurately detected, a specific location can be arranged without limitation.

15 is a view showing a state in which a fine dust suction module is added to a fine dust collecting device using static electricity according to a preferred embodiment of the present invention.

For a preferred description of the present invention will be described on the basis of the drawings formed in a state in which the fine dust suction module (100b) and the fine dust removal module (100a) is connected. A mesh network 910 provided at the entrance of the fine dust suction module 100b, a fan 920 provided at a rear end of the mesh network 910, and ultrasonic waves provided at a rear end of the fan 920 Part 930 may be included. The ultrasonic module 930 according to the preferred embodiment of the present invention may increase the dust collection efficiency by increasing the diameter of the fine dust sucked into the fine dust suction module 100b.

In addition, the fine dust suction module 100b according to a preferred embodiment of the present invention may be made of a configuration in which the heating member 935 is further provided. The heating member 935 according to a preferred embodiment of the present invention can evaporate by adding heat to the water vapor floating together with fine dust. Therefore, there is an effect of preventing rusting by water vapor and an effect of preventing the reduction of electrostatic generation efficiency. The heating member 935 according to the preferred embodiment of the present invention may be made of a thermoelectric element. However, if it has a function of evaporating water vapor, a member other than the thermoelectric element can be sufficiently used.

16 is a view showing a state in which a modified form of the fine dust suction module is added to the fine dust collecting device using static electricity according to a preferred embodiment of the present invention.

The fine dust suction module 100b according to another embodiment of the present invention further includes a mesh network 910, a fan 920, an ultrasonic generator 930, a cyclone unit 940, and a Venturi tube 950. Can be done with a configuration.

The cyclone unit 940 separates fine dust having a high hardness to the bottom of the cyclone unit 940 and fine dust having a small hardness to the top of the cyclone unit 940 according to the hardness of the fine dust after introducing the fine dust. It has the effect of further increasing the dust collection efficiency. In addition, the rear end of the fine dust suction module 100b may be formed in the form of a venturi tube 950. Therefore, the venturi tube 950 is located at the rear end of the fine dust suction module 100b, and has the effect of reducing the kinetic energy of the fine dust when the fine dust flows into the fine dust removal module 100a.

17 is a view showing a driving sequence of a fine dust collecting apparatus using static electricity according to a preferred embodiment of the present invention.

The step of driving the fine dust collecting apparatus 100 using static electricity according to FIG. 17 is a step in which the motor 400 rotates (S17-1), and the power transmission shaft 430 rotates by rotation of the motor 400 Step (S17-2), the rotational force is transmitted by the power transmission shaft 430, the first rotating friction member 250 and the second rotating friction member 350 rotates (S17-3) Can be done with

When the first rotating friction member 250 and the second rotating friction member 350 are rotated (S17-3), each of the first fixed friction member 260 and the second fixed friction member 360 is rotated. It can rub and charge each other. Subsequently, the first static electricity induction member 270 and the second static electricity induction member 370 may be charged (S17-4). Since the first static electricity induction member 270 and the second static electricity induction member 370 are connected to the first static electricity plate 184 and the second static electricity plate 185 along the static electricity induction line 500, the first static electricity plate 184 ) Is charged with a polarity opposite to the first static electricity induction member 270, and the second static electricity plate 185 can be charged with a polarity opposite to the second static electricity induction member 370 (S17-5). have.

18 is a view showing a sequence in which the rotational speed of the motor is adjusted according to a preferred embodiment of the present invention.

After the step (S18-1) in which the controller 700 receives the humidity value from the humidity sensor 750 in FIG. 18, it determines whether the preset humidity value is exceeded and adjusts the rotation speed of the motor 400 Step S18-2 may be continued. Thereafter, the rotation speed of the motor 400 is adjusted to transmit power to the power transmission shaft 430 (S18-3). If the humidity information received by the control unit 700 is greater than or equal to a preset value, the rotation speed of the motor 400 may be controlled to increase. When the rotation speed of the motor 400 increases, the power transmitted to the power transmission shaft 430 increases, and more electrostatic force can be produced. Therefore, it is possible to prevent a phenomenon in which static electricity generation efficiency decreases due to the electronic exchange of the first static plate 184 and the second static plate 185 by water vapor in wet weather.

On the other hand, if the humidity information received by the control unit 700 is equal to or less than a preset value, the rotation speed of the motor 400 may be controlled to decrease. When the rotation speed of the motor 400 decreases, electricity consumed to rotate the motor 400 is saved.

19 is a view showing an order in which the replacement time of the dust collecting sheet according to the preferred embodiment of the present invention is determined.

According to FIG. 19, after the first electrostatic plate 184 and the second electrostatic plate 185 are charged and fine dust is collected (S19-1), the amount of fine dust collected inside and outside the dust collecting sheet 170 is measured. It may lead to the measuring step (S19-2), after measuring the amount of dust collecting sheet 170, determining the replacement time of the dust collecting sheet 170 according to the amount of dust collection (S19-3) Can lead to

After determining the replacement time of the dust collecting sheet 170, it may lead to a step (S19-4) of sending out the replacement time of the dust collecting sheet 170, and the user who has received the replacement time of the dust collecting sheet 170 is collected The seat 170 can be replaced and repaired to provide convenience.

20 is a view showing a driving sequence of a fine dust collecting device using static electricity when a fine dust suction module is mounted according to a preferred embodiment of the present invention.

When the fine dust is floating in the air according to FIG. 20, after the step of inhaling the input dust by operating the fan 920 (S20-1), the ultrasonic generator 930 operates to collect fine dust. Step S20-2 may be followed. More specifically, the step of collecting the fine dust by the operation of the ultrasonic generator 930 (S20-2) is a step of applying energy to the fine dust so as to induce aggregation to be formed into a large fine dust. Accordingly, the coarse fine dust is first collected in the filter region 174 of the dust collecting sheet 170 and has an effect that can be removed before entering the fine dust removal module 100a. Thereafter, it can be seen that the process after the step S20-3 in which the motor 400 is operated is the same as the driving sequence of the fine dust collecting apparatus 100 using static electricity according to a preferred embodiment of the present invention.

21 is a view showing a driving sequence of a fine dust collecting device using static electricity when a fine dust suction module is mounted according to another embodiment of the present invention.

When the fine dust suction module 100b is added according to another embodiment of the present invention, after the step S21-1 of sucking the fine dust by rotating the fan 920, through the cyclone unit 940 The fine dust may be classified according to the particle size (S21-2), and the heating member 935 may be heated to heat the fine dust and evaporate water vapor (S21-3), followed by an ultrasonic generator 930 It may lead to the step of cohesively coagulating fine dust (S21-4). Subsequently, passing through the venturi tube 950, discharged to the outlet of the fine dust suction module 100b, passing through the filter area 174 provided in the dust collecting sheet 170 of the fine dust removal module 100a. (S21-5). The following steps (S21-6) will be followed when the fine dust collecting device 100 using static electricity according to the preferred embodiment of the present invention and the fine dust suction module 100b according to the preferred embodiment of the present invention, the fine using static electricity Since it is equivalent to the driving sequence of the dust collecting device 100, a detailed description will be omitted.

As described above, although described with reference to the preferred embodiments of the present invention and another embodiment of the present invention, those skilled in the art will not depart from the spirit and scope of the present invention as set forth in the claims below. It will be understood that the present invention can be variously modified and changed within.

10: Fine dust device using conventional static electricity previously registered by the applicant
30: fine dust collection system using the principle of corona discharge
100 Dust collection device using static electricity
100a: fine dust removal module
100b: fine dust suction module
170: dust collecting sheet
171: first dust collection area
172: second dust collection area
173: moisture absorption area
174: filter area
184: first electrostatic plate
185: second electrostatic plate
200: first static electricity generating unit
250: first rotating friction member
260: first fixed friction member
265: first elastic member
265a: first elastic spring
265b: first friction pad
265c: first friction brush
270: first electrostatic induction member
300: second static electricity generating unit
350: second rotating friction member
360: second fixed friction member
365: second elastic member
365a: second elastic spring
365b: second friction pad
365c: second friction brush
370: second electrostatic induction member
400: motor
430: power transmission shaft
500: electrostatic induction wire
700: control
750: humidity sensor
770: dust detection sensor
774: differential pressure measurement sensor
775: photo sensor
910: mesh network
920: fan
930: ultrasonic module
935: heating member
940: cyclone section
950: Venturi Hall

Claims (30)

Fine dust suction module;
It comprises a; fine dust removal module provided at the rear end of the fine dust suction unit,
The fine dust suction module
A mesh network provided at the entrance of the fine dust suction module;
A fan provided at a rear end of the mesh network;
It is configured to include; an ultrasonic generator provided at the rear end of the fan,
The fine dust removal module
A first electrostatic plate;
A second electrostatic plate;
At least one first static electricity generator;
At least one second static electricity generator;
And static electricity induction wires connecting between the first static electricity plate and the first static electricity generating part and connecting between the second static electricity plate and the second static electricity generating part. Dust collector.
According to claim 1,
The fine dust removal module
It comprises a dust collecting sheet (sheet);
The dust collecting sheet
A filter area corresponding to the inlet of the fine dust removal module;
A first dust collecting region corresponding to the first electrostatic plate;
And a second dust collecting region corresponding to the second electrostatic plate.
The first dust collection area covers all of the upper side of the first electrostatic plate, and the second dust collection area covers all of the upper side of the second electrostatic plate, so that the filter area opens the entrance of the fine dust removal module. Fine dust collecting device using static electricity, characterized by covering all.
According to claim 2,
The dust collecting sheet
Static electricity, characterized in that further comprises; each of the ends of the dust collecting sheet, between the first dust collecting region and the second dust collecting region, provided between the filter region and the first dust collecting region; Fine dust collection system using.
According to claim 1,
The fine dust suction module
Heating member provided on the rear end of the mesh network; fine dust collecting apparatus using static electricity, characterized in that further comprises a.
According to claim 1,
The fine dust removal module
A power transmission shaft connected to the first static electricity generator and the second static electricity generator;
A fine dust collecting device using static electricity, further comprising; a motor (motor) for transmitting a rotational force to the power transmission shaft.
According to claim 1,
The first static electricity generating part
A first rotating friction member coupled with the power transmission shaft and rotating together;
A first fixed friction member in close contact with the first rotating friction member;
The first rotational friction member is installed spaced apart, and the first static electricity induction member connected to the first static electricity plate through the static electricity induction wire;
The second static electricity generating part
A second rotating friction member coupled with the power transmission shaft and rotating together;
A second fixed friction member in close contact with the second rotating friction member;
And a second static electricity induction member installed spaced apart from the second rotating friction member and connected to the second static electricity plate through the static electricity induction wire.
The method of claim 6,
The first rotating friction member is coupled to the power transmission shaft and gear (gear) to rotate,
The first fixed friction member is in close contact with an outer circumferential surface on which the gear of the first rotational friction member is not formed,
The second rotating friction member is rotated in gear engagement with the power transmission shaft,
The second fixed friction member is a fine dust collecting device using static electricity, characterized in that the second rotary friction member in close contact with the outer peripheral surface of the gear is not formed.
The method of claim 6,
The first rotating friction member is circular,
The second rotating friction member is a fine dust collecting device using static electricity, characterized in that the circular.
The method of claim 6,
The first corrector induction member
It is formed in an arc shape and is provided at a position symmetric to the first fixed friction member,
The second static electricity induction member
It is formed in an arc shape and is provided at a position symmetric to the second fixed friction member.
The method of claim 6,
The first fixed friction member is in close contact with the first rotating friction member by the elastic force of the elastic member,
The second fixed friction member is in contact with the second rotating friction member by the elastic force of the elastic member fine dust collecting device using static electricity.
The method of claim 6,
The first rotating friction member and the first fixed friction member use different materials as friction materials,
The friction material of the first rotating friction member loses charge better than the friction material of the first fixed friction member,
The second rotating friction member and the second fixed friction member use different materials as friction materials,
The friction material of the second fixed friction member loses electric charges better than the friction material of the second rotational friction member.
According to claim 1,
The fine dust removal module
Humidity sensor;
A dust collecting device using static electricity, characterized in that further comprising; a control unit for adjusting the rotational speed of the motor based on the humidity value measured by the humidity sensor.
The method of claim 12,
The control unit
If the humidity value measured by the humidity sensor is higher than a preset value, the rotation speed of the motor is increased,
If the humidity value measured by the humidity sensor is less than a predetermined value, the dust collecting device using static electricity, characterized in that for reducing the rotational speed of the motor.
According to claim 2,
The fine dust removal module
Dust collection device using static electricity, characterized in that it further comprises; a dust collection sensor for measuring the amount of dust collected on the dust sheet.
Filter area;
A first dust collection area;
A second dust collection area;
A dust collecting sheet comprising; between the filter region and the first dust collecting region, between the first dust collecting region and the second dust collecting region, and a water absorption region provided at both ends.
A fan operating;
A step of operating the ultrasonic generator;
A step in which the motor operates;
The power transmission shaft rotates together as the motor operates;
Rotating the first rotational friction member of the one or more first static electricity generating units and the second rotational friction member of the one or more second static electricity generating units as the power transmission shaft rotates;
Friction with the first fixed friction member as the first rotating friction member rotates and friction with the second fixed friction member as the second rotating friction member rotates;
A step in which a first static electricity induction member is charged in the opposite polarity to the first rotating friction member, and a second static electricity induction member is charged in the opposite polarity to the second rotating friction member;
The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. Step; Method of driving a fine dust collecting apparatus using static electricity, characterized in that it comprises a.
The method of claim 16,
After the fan is running,
Heating air sucked into the fine dust suction module through the heating member;
The air passing through the fan passing through the cyclone; driving method of a fine dust collecting apparatus using static electricity, further comprising a.
The method of claim 16,
After the operation of the ultrasonic generator,
Static electricity, characterized in that further comprising; passing through the outlet of the fine dust suction module is made in the form of a Venturi tube, sucked into the fine dust suction module through the filter area of the dust collecting sheet into the fine dust removal module; Method of driving a fine dust collecting device using a.
The method of claim 16,
The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. After the step,
The control unit receives the humidity value measured by the humidity sensor;
And controlling the rotation speed of the motor based on the humidity value measured by the humidity sensor by the control unit; further comprising a static dust collecting device using static electricity.
The method of claim 19,
The control unit adjusting the rotation speed of the motor based on the humidity value measured by the humidity sensor is
If the humidity value measured by the humidity sensor is greater than or equal to a preset value, the control unit increases the rotation speed of the motor,
When the humidity value measured by the humidity sensor is less than a predetermined value, the control unit is achieved by reducing the rotational speed of the motor Method for driving a fine dust collecting device using static electricity.
The method of claim 19,
The first static electricity plate connected to the first static electricity induction member and the second static electricity plate connected to the second static electricity induction member are charged in opposite polarities to the first static electricity induction member and the second static electricity induction member through the static electricity induction wire, respectively. After the step,
A step in which the control unit receives a measurement value for the amount of dust collected in the dust collecting sheet from the dust collection sensor;
Further comprising: when the measured value for the amount of dust collected on the dust collecting sheet corresponds to a predetermined replacement value, the control unit transmits information indicating that it is time for the dust collecting sheet to be replaced; How to drive the dust collector.
The control unit receives the humidity value measured by the humidity sensor;
And controlling the rotational speed of the motor based on the humidity value measured by the humidity sensor by the control unit.
The method of claim 22,
The control unit adjusting the rotation speed of the motor based on the humidity value measured by the humidity sensor is
If the humidity value measured by the humidity sensor is greater than or equal to a preset value, the control unit increases the rotation speed of the motor,
When the humidity value measured by the humidity sensor is less than a predetermined value, the control unit is achieved by reducing the rotational speed of the motor Method for driving a fine dust collecting device using static electricity.
A step in which the control unit receives a measurement value for the amount of dust collected in the dust collecting sheet from the dust collection sensor;
When the measured value for the amount of dust collected on the dust collecting sheet corresponds to a preset replacement value, the control unit transmits information indicating that it is time to replace the dust collecting sheet. Method of driving the used fine dust collector.
The method of claim 16,
The first rotational friction member is geared and rotates with the power transmission shaft,
The first fixed friction member is in close contact with an outer circumferential surface on which the gear of the first rotational friction member is not formed,
The second rotating friction member is rotated in gear engagement with the power transmission shaft,
The second fixed friction member is a method for driving a fine dust collecting apparatus using static electricity, characterized in that the second rotary friction member is in close contact with an outer circumferential surface on which no gear is formed.
The method of claim 16,
The first rotating friction member is circular,
The second rotating friction member is a method of driving a fine dust collecting device using static electricity, characterized in that the circular.
The method of claim 16,
The first electrostatic induction member
It is formed in an arc shape and is provided at a position symmetric to the first fixed friction member,
The second static electricity induction member
It is formed in an arc shape and is provided at a position symmetric to the first fixed friction member.
The method of claim 16,
The first fixed friction member is in close contact with the first rotating friction member by the elastic force of the elastic member,
The second fixed friction member is a method for driving a fine dust collecting device using static electricity, characterized in that in close contact with the second rotating friction member by the elastic force of the elastic member.
The method of claim 16,
The first rotating friction member and the first fixed friction member use different materials as friction materials,
The friction material of the first rotating friction member loses charge better than the friction material of the first fixed friction member,
The second rotating friction member and the second fixed friction member use different materials as friction materials,
The friction material of the second fixed friction member loses electric charges better than the friction material of the second rotational friction member.
The method of claim 18, 21 or 24,
The dust collecting sheet
A filter area corresponding to the inlet of the fine dust removal module;
A first dust collecting region corresponding to the first electrostatic plate;
A second dust collecting region corresponding to the second electrostatic plate;
Each of both ends of the dust collecting sheet, between the filter region and the first dust collecting region, provided between the first dust collecting region and the second dust collecting region; is made, including,
Method of driving a fine dust collecting apparatus using static electricity, characterized in that the moisture absorption region contains a silica gel or an activated carbon component.

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