KR19980018670A - Air purifier - Google Patents

Abstract

In the electronic air purifier, the dust collecting efficiency is increased.

The first and second dust collecting electrodes 2 and 3 are disposed on the outer circumferential surface of the cylindrical support 4. The fan 16 is disposed above the cylindrical support 4. The cylindrical cover 11 is installed to surround the cylindrical support 4 and the fan 16. An air inlet 19 is provided below the cover 11. An air outlet 20 is provided on the upper surface portion 18 of the cover 11. Air is forced to flow along the first and second dust collecting electrodes 2 and 3 through the fan 16.

Description

Air purifier

The present invention relates to an air purifier of a type in which dust is ionized and collected.

Corona discharge is generated between the ionizing electrode and the collecting electrode, and ionized dust is suspended in the air, i.e., micro particles (for example, dust, bacteria, viruses, dust mites secretions, pollen, etc.) An ion, electrostatic or electronic air purifier is known as a device for moving toward the dust collecting electrode and adsorbing the dust collecting paper disposed on the front surface of the dust collecting electrode.

Moreover, the electric dust collector of the structure which forcibly circulates air by a fan, arrange | positions a filter in an air path, and arrange | positions the dust collection electrode is also known.

However, in the conventional electrostatic air purifier without a fan as in the former, a phenomenon in which unipolar ions move in a specific direction under a direct current electric field, that is, an electrode collecting dust ionized using ion wind is used. It is comprised so that it may convey on the dust collecting cover which covers, and will adsorb | suck to a dust collecting site by coulomb force, and hold | maintain. However, since the ion wind only flows within the range of a few mm from the dust collecting electrode, it is difficult to circulate air well in a wide room. Therefore, the conventional electrostatic air purifier has a property of long lasting dust collecting effect, but the effect is not rapid. Also, if the air is not circulated in a large room, some large dust will fall out of the room before it is collected.

While the latter is equipped with a fan, it is easy to remove relatively large particles and tobacco smoke with moisture, but because of the relatively high air volume, the microparticles are easily passed through the dust collecting electrode, making it difficult to remove them sufficiently. Have That is, relatively large particles are collected along a forced air stream, and tobacco smoke is likely to be collected through adhesion by moisture. However, even if it is adsorbed once, the fine microparticles are peeled off by wind, and dust collection efficiency is bad. In addition, in the apparatus in which a conventional fan is used, noise is a problem because the fan is rotated at a relatively high speed.

Accordingly, an object of the present invention is to provide an air cleaning apparatus which can enhance the dust collecting effect and can suppress the noise caused by the fan.

1 is a longitudinal cross-sectional view showing an air cleaning apparatus which is an embodiment of the present invention.

FIG. 2 is a perspective view of the air cleaner of FIG. 1 excluding a cover, a fan, and a motor.

3 is a front view of the air cleaning device of FIG. 1.

FIG. 4 is an enlarged cross-sectional view of a second dust collecting electrode and a dust collecting part of the air cleaning device shown in FIG. 1.

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

1: ionization electrode 2: first dust collecting electrode

3: second dust collecting electrode 4: support

6: dust collector 16: fan

In order to achieve the above object, the present invention is provided with a support of an ionizing electrode, a dust collecting electrode, the ionizing electrode and a dust collecting electrode, and dust is placed on the dust collecting sheet by arranging the dust collecting sheet to be in contact with the surface of the dust collecting electrode. An air purifier having an adsorption structure, wherein a fan for forcibly generating wind of 5 mm / sec or less in the vicinity of the dust collecting electrode, a drive motor of the fan, and an air passage forming means are provided. Relates to a device.

The invention according to claim 2 further comprises an insulating cylindrical body, an ionization electrode arranged to surround the lower side of the cylindrical body at a distance from the cylindrical body, and fixed to an outer circumferential surface of the cylindrical body to surround the cylindrical body. A dust collecting electrode formed so as to cover the cylindrical body, a fan disposed above the cylindrical body, a motor for driving the fan, the cylindrical body, an ionizing electrode, a dust collecting electrode, a fan, and a motor, and the vicinity of the ionizing electrode. It relates to an air purifying device having a cover having an air inlet port, an air outlet port above the fan, and a portion surrounding the dust collecting electrode in a cylindrical shape.

Example

Next, with reference to FIGS. 1-4, the electrostatic air cleaning apparatus which concerns on embodiment of this invention is demonstrated.

As shown in Figs. 1 and 2, the air purifier includes an ionization electrode (cathode) 1 to which -6 kV is applied, and a first dust collection electrode 2 of ground potential, for example. For example, the second dust collecting electrode 3 to which 6 kV is applied is provided. The ionization electrode 1 is formed in a cylindrical shape and has a plurality of needle-like protrusions 1a. The 1st and 2nd dust collecting electrodes 2 and 3 are strip | belt-shaped metal plates, and are wound in the round annular shape on the surface of the cylindrical insulating support body 4 whose diameter is smaller than the cylinder of the ionization electrode 1. The first dust collecting electrode 2 is disposed near the ionization electrode 1, and the second dust collecting electrode 3 is disposed at a position away from the first dust collecting electrode 2 with respect to the ionizing electrode 1.

In the hollow part 5 of the cylindrical support body 4, the dust collecting roll 6a which rolled up the dust collecting paper 6 which functions as a dust collecting sheet which has insulation and flexibility is rolled. Moreover, the shaft 7 is provided in order to determine the rotatable position of the dust collecting roll 6a, and the groove | channel for pulling out the dust collecting paper 6 from the hollow part 5 in the wall surface of the cylindrical support body 4 ( 8) is installed. The dust collecting paper 6 is pulled from the groove 8 and wound around the entire outer circumferential surface of the cylindrical support 4 to cover the first and second dust collecting electrodes 2, 3, and the fixing member 9 shown in FIG. 1. Is fixed to the cylindrical support 4. The ionization electrode 1 is fixedly attached to the table-like insulating support 10. The table-like support 10 is provided with an end portion 12 for determining the position of the cover 11, which is an air passage forming means shown in the drawing. In addition, the table-like support 10 supports the cylindrical support 4 and houses the electric passage device 13 therein.

A cover 14 is installed on the upper portion of the cylindrical support 4 so as to be attached and detached as shown in FIG. 1, and a motor 15 is fixedly attached to the center of the upper surface of the cover 14. The fan 16 is coupled to the motor 15. The motor 15 is connected to a power source so as to be driven in synchronization with the ionization electrode 1 and the dust collection electrodes 2 and 3. That is, the motor 15 is always driven.

The cover 11 which functions as an air passage formation body is a shape which cupped, and consists of the cylindrical part 17 and the upper surface part 18. As shown in FIG. As shown in FIG. 3, a plurality of air inlets 19 are provided in a slit shape on the entire outer circumferential surface of the cylindrical portion 17 near the ionization electrode 1 below the cylindrical portion 17. The upper surface portion 18 is provided with a plurality of air outlets 20 as shown in FIG. An opening is not provided in the area | region opposing the dust collection electrodes 2 and 3 in the cylindrical part 17 of the cover 11. Thus, the space between the cylindrical support 4 and the cylindrical portion 17 of the cover 11 becomes the air passage 21.

The second dust collecting electrode 3 of the present embodiment is made of a metal plate (aluminum plate) in which a plurality of small holes 22 having a diameter of 0.5 / 5 mm and an area of about 0.39 to 39.25 mm are formed. The function of the small hole 22 will be described later.

*action

For example, when −6 kV is applied to the ionization electrode 1, 0 V is applied to the first dust collecting electrode, and +6 kV is applied to the second dust collecting electrode 3, the ionization electrode 1 and the first and second dust collecting electrodes serving as cathodes ( Corona discharge occurs between 2 and 3, and a large amount of electrons are emitted from the ionization electrode 1 toward the first and second dust collecting electrodes 2 and 3. Electrons emitted by the corona discharge anionize air molecules (particularly oxygen molecules). Dust suspended in air (eg, dust, bacteria, viruses, dust mites secretions, pollen, etc.) receives electrons from negative ions and becomes negatively charged particles, ie anionized dust. Since the first and second dust collecting electrodes 2 and 3 have a high potential when the ionizing electrode 1 is referred to, they are in a positively charged state, and the anionized dust and the dust collecting electrodes 2 and 3 are separated from each other. As the coulomb force acts between both charges, the anionized dust moves toward the dust collecting electrodes 2 and 3 and is adsorbed by the dust collecting paper 6 wound on the outer circumferential surface of the cylindrical support 4. In addition, a phenomenon in which unipolar ions move in a specific direction under a DC electric field, that is, ion wind occurs. Thus, in the apparatus of FIGS. 1 and 2, ion wind is generated from the ionization electrode 1 toward the first and second dust collecting electrodes 2, 3. That is, ion wind is generated from the lower side of the cylindrical support 4 to the upper side. In addition, the first dust collecting electrode 2 disposed in the middle portion between the ionizing electrode 1 and the second dust collecting electrode 3 serves to not only uniformize the potential distribution but also to generate the ion wind satisfactorily.

The ionized dust moving by the ion wind may be collected by being adsorbed by the dust collecting paper 6, but as described above, a rapid dust collecting effect and a high dust collecting efficiency are not possible. Here, in this embodiment, the motor 15 is driven at the same time as the ionization electrode 1 and the dust collecting electrodes 2 and 3 are driven to rotate the fan 16 gradually.

The fan 16 is formed in the shape which moves air from below to upward. Therefore, when the fan 16 is rotated, the lower side of the fan 16 becomes a depressurized state, and air flows inward from the outside of the cover 11 through the air inlet 19 under the cover 11. The air is discharged outward from the air outlet 20 formed in the upper surface 18 of the cover 11 through the air passage 21. The airflow forcibly formed in the air passage 21 by the fan 16 is adjusted to be at or near the speed of the ion wind. Since the wind speed of the ion wind is about 1 m / sec to 5 m / sec according to the actual measurement, the flow rate of air forcibly generated by the fan 16 is preferably 5 m / sec or less, for example, 1 to 5 m / sec. It is the range of, More preferably, it is the range of 2-3m / sec. Such airflow is obtained by slowly rotating the fan 16, and when the fan 16 is rotated slowly, the noise level by the fan 16 is extremely reduced. When the air flow is formed by the rotation of the fan 16, air flow, that is, circulation occurs around the air cleaning device in the room, and contaminated air in the room flows into the air inlet 19 of the cover 11, and the air While passing through the passage 21, it is cleaned and discharged from the air outlet 20 into the room. When the air flow is formed by the fan 16, the contaminated air in the room may be introduced into the air cleaning device to increase the cleaning speed as described above, and the dust falling to the floor in the room may be sucked into the air cleaning device. Therefore, dust collection efficiency is improved. In addition, since the airflow forcibly generated by the fan is close to the ion wind, it works to compensate for the weakness of the ion wind, and uniforms dust on the light area of the dust collecting region 6 according to the large area of the dust collecting electrode 3. Since this can be made to adhere satisfactorily, dust collection efficiency improves. Moreover, since the air flow by the fan 16 is not very fast, the phenomenon that the dust adsorbed to the dust collecting paper 6 is peeled off by the wind hardly occurs. In addition, even dust that is not ionized is attached to the dust collecting region 6 when the dust is conveyed to the dust collecting region having a humidity of 30% or more through the air flow generated by the fan 16, and the dust collecting electrode 3 of the dust collecting region 6 is attached. When dust adheres to a region where the action of the electric field based on the dust does not occur, the dust is retained by the humidity of the dust collector 6.

Next, the operation of the small hole 22 of the dust collecting electrode 3 will be described. For example, when the dust collecting paper 6 having a flexibility such as a paper towel is wound on the cylindrical support 4 provided with the collecting electrodes 2 and 3, a part of the dust collecting paper 6 is removed as shown in FIG. 4. It becomes the state which dug in the small hole 22, and the unevenness along the small hole 22 arises in the surface besides the essential unevenness which the dust collecting paper 6 has. Since the coulomb force effectively acts on the ionized dust at a distance of about 1 mm from the first and second dust collecting electrodes 2 and 3, when the dust collecting paper 6 has a thickness of 1 mm or less, the dust collecting paper ( The coulomb force acts not only on the region in contact with the first and second dust collecting electrodes 2, 3 in 6) but also on the ionized dust in the region located in the small hole 22. Therefore, the small hole 22 part of the dust collecting paper 6 also contributes to dust collection by the coulomb force. In addition, when the humidity is 30% or more, the region not in contact with the dust collecting electrodes 2 and 3 of the dust collecting paper 6 functions as an adsorption surface of the ion wind or the dust moved by the fan 16. Therefore, when the small hole 22 is relatively large, the region adjacent to the small hole 22 of the dust collecting region 6 not only functions as an adsorption surface by the coulomb force but also moves by the ion wind or the fan 16. It also functions as an adsorption surface for the collected dust, and the center region functions as an adsorption surface for the dust moved by the ion wind or the fan 16. As can be seen from the above description, the effect of increasing the surface area of the dust collecting paper 6 by the small holes 22 is obtained, and the dust adsorbed to the small hole 22 region of the dust collecting paper 6 is difficult to peel off. It is possible to increase dust collection efficiency.

Modification

The present invention is not limited to the above embodiments, and the following modifications are possible, for example.

(1) The second dust collecting electrodes 3 can be divided into two or more. In addition, the first dust collecting electrode 2 can be divided into a plurality of parts.

(2) The structure which abbreviate | omitted the 1st dust collecting electrode 2 is possible.

(3) The structure which provided the small hole also in the 1st dust collection electrode 2 like the 2nd dust collection electrode 3 is possible. In this case, it is preferable that the small holes of the first dust collecting electrode 2 are uniformly distributed with respect to the ionizing electrode 1.

(4) A filter for removing dust in the air that cannot be removed from the dust collecting paper 6 may be added.

(5) The voltage of the ionization electrode 1 can be added in an offset state such as -4 kV, the voltage of the first dust collecting electrode 2 +2 kV, and the voltage of the second dust collecting electrode 3 +8 kV. The voltage of 1) can be added in an offset state such that -8 kV, the voltage of the first dust collecting electrode 21 is -2 kV, and the voltage of the second dust collecting electrode 3 is +4 kV. That is, a voltage having a different absolute value can be applied to the ionization electrode 1 and the second dust collecting electrode 3.

(6) It is possible to prevent the dust collecting paper 6 from being disposed on the first dust collecting electrode 2.

According to the invention of each claim, the following effects are obtained.

(1) The airflow, that is, circulation occurs inside the room by the fan, and the dust collection speed can be increased.

(2) In the case of an air purifier without a conventional fan, in the case of an air purifier equipped with a fan according to the present invention, some dust which has not been adsorbed and dropped on the floor is blown by airflow to the air purifier. Is reached and adsorbed by the sheet for dust collection, and as a result, dust collection efficiency is improved.

(3) The airflow by the fan functions to assist the ion wind, the airflow is well generated over the entire area of the dust collecting sheet, and dust is effectively adsorbed to the dust collecting sheet.

(4) A low noise state can be maintained by driving the fan so that an auxiliary flow to the ion wind is formed.

Further, according to claim 2, since the dust collecting electrode is fixedly attached to the outer circumferential surface of the cylindrical body and the cover is provided so as to surround the cylindrical body, ionized dust and airflow can be satisfactorily generated between the cylindrical body and the cover. .

Claims (2)

An air purifier having an ionizing electrode, a dust collecting electrode, a support of the ionizing electrode, and a dust collecting electrode, and having a dust collecting sheet arranged to be in contact with the surface of the dust collecting electrode, adsorbing dust on the dust collecting sheet, And a fan for forcibly generating wind of 5 m / sec or less in the vicinity of the dust collecting electrode, a drive motor of the fan, and air passage forming means. With insulating cylinder, An ionization electrode arranged to surround the cylindrical body at a distance from the cylindrical body, A dust collecting electrode fixed to an outer circumferential surface of the cylindrical body and formed to surround the cylindrical body; A fan disposed above the cylindrical body, A motor for driving the fan, A portion which covers the cylindrical body, the ionization electrode, the dust collecting electrode, the fan, and the motor, has an air inlet in the vicinity of the ionizing electrode, has an air outlet above the fan, and surrounds the dust collecting electrode in a cylindrical shape. An air cleaning device having a cover.