KR20120103326A - Method for controlling cluster ionizer and cluster ionizer for duct - Google Patents

Abstract

PURPOSE: An ion generator capable of removing harmful materials in a duct and a control method thereof are provided to sterilize and purify the inner space of an air conditioner duct installed in a vehicle or a building. CONSTITUTION: An ion generator capable of removing harmful materials in a duct comprises an ion generator(100), a rotary unit, a driving part, a sensor part(400), and a control part(500). The ion generator is installed in a duct. The rotary unit is comprised in the duct and rotates ion generator. The driving part supplies torque to the rotary unit. The sensor part detects the air pollution in the duct. The control part controls the generating quantity of ion and the rotational speed of the ion generator based on the level of the inner air pollution of the duct. [Reference numerals] (500) Control part

Description

Duct ion generator and control method of ion generator using same {Method for Controlling Cluster Ionizer and Cluster Ionizer for Duct}

The present invention relates to an ion generating device, and more particularly, to an ion generating device for a duct installed in a duct provided in a duct or a vehicle air conditioner provided in various buildings to remove harmful substances inside the duct and the same. A control method of an ion generating device used.

In general, a duct installed inside a building or an air conditioning duct installed inside an automobile accumulates air pollutants that generate bacteria over time and remains inside the duct.

Referring to FIG. 1, conventionally, a large amount of accumulated pollutants have been generated inside the duct 10 while the duct 10 is used for a long time, and the pollutants may be exposed to human health such as bacteria or viruses. Attention has to be paid to the presence of a large amount of adverse substances.

The duct 10 is partially removed by a filter (not shown) for filtering various foreign substances or pollutants contained in the outside air, but is changed inside the duct 10 while heating or cooling is performed. Due to temperature and humidity changes, a large amount of bacteria 2 is present inside the duct 10. The bacteria (2) is moved and discharged into the indoor space by the flow rate of the air supplied to the duct 10, enters the respiratory apparatus of the person in the indoor space to cause various diseases.

Conventionally, in order to prevent contaminants from accumulating in the duct 10 and to remove residual particles or bacteria, the duct 10 may be periodically cleaned or a separate filter may be installed.

However, there is a cost, and there is a problem in that it is difficult to periodically clean the inside of the duct (10). In addition, a method of installing a separate filter also causes a problem that the fan power of the blower is increased by the differential pressure generated before and after the filter, and air is not stably discharged to the indoor area.

The contaminants may include volatile organic compounds such as benzene, formaldehyde, and toluene, bacteria, viruses, various harmful substances, and odorous substances, so that the air discharged through the duct 10 may be stably. There was a need for technical countermeasures to clean up and supply them to users.

Duct ion generator according to an embodiment of the present invention by installing a rotatable ion generator inside the air conditioning duct installed in the duct or vehicles installed in various buildings, the duct in conjunction with the pollution state of the duct and the operating state of the air conditioner To minimize harmful substances remaining inside.

The ion generator for ducts according to an embodiment of the present invention is to adjust the amount of ion generation generated in the ion generator according to the amount of pollutants remaining in the duct.

An ion generator for ducts according to an embodiment of the present invention includes an ion generator provided inside a duct; A rotating part provided in the duct, the rotating part allowing the ion generator to rotate; A driving unit providing a rotational force to the rotating unit; A detector for detecting an air pollution level in the duct; And a control unit for controlling the rotational speed of the ion generator, and the ion generation amount of the ion generator according to the degree of air pollution inside the duct.

The ion generator is disposed in either the longitudinal direction or the transverse direction inside the duct.

The ion generator is disposed along the longitudinal direction of the duct, and includes a cation generator for generating cations and anion generator for generating anions.

In the ion generator, a cation generator and an anion generator are alternately spaced apart.

The cation generator and the anion generator are spaced apart from each other in the center of the duct in the longitudinal direction.

The ion generator includes a plurality of cation generators spaced apart from each other, spaced apart from the cation generator, and a plurality of anion generators spaced apart from each other.

The cation generator and the anion generator includes a cation and anion pins extending outward, the anion pin is characterized in that a brush type made of carbon fiber is used to maximize the discharge area of the anion do.

Fins of the cation and anion generators extend in all directions of the cation generator and the anion generator.

The rotating unit may include a rotating shaft disposed inside the duct and into which a cation generator and an anion generator are respectively inserted; It is provided on both ends of the rotary shaft, and comprises a support member for achieving stable rotation and support of the rotary shaft at the same time.

The cation generator and the negative ion generator provided on the rotary shaft are spaced apart from each other along the longitudinal direction of the rotary shaft.

The driving unit includes a motor having a motor shaft; And a power transmission member provided to transmit the rotational force generated by the motor to the rotational shaft.

When the degree of contamination in the duct is greater than or equal to the reference value, the controller is configured to control the motor's revolutions per minute (rpm) to increase and to generate an ion generation amount in the ion generator.

The ion generator may be installed in a duct installed in a building or an air conditioning duct of an automobile.

The control method of the ion generating device for ducts according to an embodiment of the present invention (a) the operating state of the air conditioner installed in the building, the pollutant contained in the supply air (Supply Air) supplied to the duct (Duct) through the air conditioner Or detecting a contamination state of the duct by a harmful substance remaining in the duct in real time; (b) transmitting the pollution state information of the duct to a duct management module or a manager terminal; And (c) the cation and anion generators are operated according to the degree of contamination of the duct, and when the internal pollution state of the duct is higher than a reference value, the cation and anion generator is rotated inside the duct and controlled to purify the inside of the duct. Characterized in that it comprises a step.

The pollution state information of the duct detected in the step (a) includes the information on each floor of the building is detected contamination, and information about a specific section of the duct installed on the floor.

Step (b) is characterized in that the transmission through the Internet network.

In the step (c), the rotational speed of the cation and anion generator is controlled in proportion to the contamination state of the duct.

In the step (c), when the air conditioner is in an on state, a voltage applied to the cation and anion generator is applied at a maximum voltage, and when the air conditioner is in an off state, the cation and anion generator is applied. It is characterized in that no voltage is applied.

Duct ion generator according to an embodiment of the present invention to sterilize and purify the air conditioning ducts installed in the ducts or vehicles installed in buildings, to create a pleasant environment for the health of the occupants, and to improve the disease incidence of workers Can be significantly reduced.

Duct ion generating device according to an embodiment of the present invention selectively purifies the duct of a particular section arranged in each floor in the building, and immediately purge the contamination occurs in the duct to contaminate the inside of the duct The accumulation of materials can be prevented to keep the interior of the duct clean.

Duct ion generator according to an embodiment of the present invention by adjusting the number of installation of the ion generator according to the size and size of the duct, to purify the air moved through the duct, or remaining in the duct It is possible to reliably remove contaminants.

1 is a perspective view showing a contaminant remaining in the conventional duct.
Figure 2 is a perspective view of the ion generating device for ducts according to an embodiment of the present invention.
3 to 4 is a perspective view showing an arrangement state of the ion generating device for ducts according to an embodiment of the present invention.
5 is a view showing a rotating part and a driving part according to an embodiment of the present invention.
6 is a view showing a control unit provided in the duct ion generator according to an embodiment of the present invention and a configuration connected to the control unit.
7 is a flow chart showing a control method of the ion generating device for ducts.
8 is a view illustrating an example of a position where an ion generating device for ducts according to an embodiment of the present invention is installed.
9 to 10 is an operation state diagram of the ion generating device for ducts according to an embodiment of the present invention.
11 is an operational state diagram of the ion generating device for ducts according to another embodiment of the present invention.

An ion generating device for a duct according to an embodiment of the present invention will be described with reference to the drawings. In the present embodiment will be described mainly around the duct is installed in the building, it is noted that the duct can be installed in the vehicle.

Referring to FIG. 2, the ion generator 100 is provided inside a duct 10 used in a building, and includes a cation generator 110 and an anion generator 120. It should be noted that the duct 10 can also be used for both small and large ducts having a length greater than or equal to 1000 mm in length and length. A detailed description of the specific arrangement state of the ion generator 100 will be described later.

The cation and anion pins provided in the cation generator and the anion generator according to the present invention will be described with reference to the drawings.

Referring to FIG. 2, the cation and anion generators 110 and 120 are provided with a cation fin 112 and an anion fin 122 through which cations and anions are discharged, and the cation fin 112 and the anion fin 122 are provided. The cation generator 110 and the anion generator 120 extend in all directions.

In more detail, the cation fin 112 and the anion fin 122 are disposed toward the front, rear, left and right sides with respect to the plane of the cation generator 110 and the anion generator 120.

Since the cation and anion generators 110 and 120 are rotated in the duct 10 by the rotating part 200, the cation fin 112 and the anion fin 122 are selectively installed only at the front and rear or left and right sides. It is also possible.

The cation and anion pins 112 and 122 are extended and have a length that does not interfere with each other while the cation and anion generators 110 and 120 rotate, and preferably have a length that does not interfere with the inner surface of the duct 10. Do.

The anion pin 122 is preferably a brush type made of carbon fiber in order to maximize the discharge area of the anion and reduce the amount of ozone, but is not necessarily limited thereto.

The cation and anion pins 112 and 122 have a diameter of 5 to 10 μm and are supplied with 220 V of input power and operated at an output voltage of 1 kv. Power supplied to the cation and anion generators 110 and 120 uses a 220V power source that is typically used in buildings, and although not shown in the drawing, an electric wire for providing power to the ion generator 100 is provided. do.

Referring to FIG. 2 or FIG. 5, the ion generator 100 includes a rotating part 200 for rotating in the state where the ion generator 100 is installed in the duct 10, and the rotating part 200 of the duct 10 is provided. It can be installed on the lower surface. The installation position of the rotating unit 200 is not necessarily limited to the above position, and when the stable rotation of the ion generator 100 is possible, it is apparent that the side surface or the upper surface of the duct 10 may be installed.

The rotating part 200 may receive a rotational force from the driving part 300 installed outside the duct, and the driving part 300 is connected to each other so that the rotating force is transmitted to the plurality of rotating parts 200. A description of a more detailed coupling relationship between the rotating unit 200 and the driving unit 300 will be described later.

In order to detect an air pollution level in the duct 10, a sensing unit 400 is installed inside the duct 10, and the sensing unit 400 is provided along a length direction of the duct 10. The dogs are each spaced apart. The sensing unit 400 is preferably installed at a position that does not interfere with the rotating ion generator 100, and transmits a sensing signal to the control unit 500 to be described later.

For example, the detection unit 400 may use a particle sensor, but is not limited thereto. The detection unit 400 may be replaced with another sensor capable of detecting a harmful substance remaining in the duct 10.

For example, 10-2010-48129 filed by the applicant of the present invention captures the airborne microorganisms contained in the air, and extracts the ATP (adenosine triphosphate) of the airborne microorganisms, using the filter provided separately Airborne microbial sensor that can measure the concentration is provided.

By doing so, after a predetermined time has elapsed after the ion generator 100 is operated, when the detection unit 400 detects a harmful substance inside the duct 10 and transmits it to the control unit 500, the control unit ( 500 may determine the contamination state of the duct 10. Therefore, the plurality of detection units 400 installed in the duct 10 accurately detects the contamination state of the duct 10 contaminated in a specific section, and the control unit 500 controls the operation of the ion generator 100 to contaminate. The generation of substances can be minimized.

The controller 500 selectively controls the rotational speed of the ion generator 100 and the amount of ion generation generated by the ion generator 100 according to the degree of air pollution in the duct 10. A more detailed description of the control state of the control unit 500 will be described later.

The ion generator 100 according to the present embodiment may be installed in a specific section of the duct 10. For example, the contaminants may be installed at the rear end of the filter (not shown) with many inflows, installed at predetermined lengths in the duct extending into the building, or installed in the duct extending toward the indoor area.

An arrangement state of an ion generator according to an embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 3A, the ion generator 100 may be installed in the longitudinal direction of the duct 10, and the cation generator 110 and the negative ion generator along the longitudinal direction of the duct 10. 120 is disposed. The ion generator 100 may be spaced apart from each other in the center of the duct 10 in the longitudinal direction, and spaced apart from each other while the cation generator 110 and the negative ion generator 120 are rotated to prevent interference from occurring. It is preferable to space apart.

Referring to FIG. 3B, the ion generator 100 may be installed in the transverse direction of the duct 10, and the cation generator 110 and the negative ion generator along the longitudinal direction of the duct 10. 120 is disposed. The ion generator 100 may be spaced apart from each other in the center of the duct 10 in the longitudinal direction, and the cation generator 110 and the negative ion generator 120 are rotated at intervals at which interference does not occur. It is preferred to be spaced apart.

The ion generator 100 is not disposed on one side of the duct 10, but is disposed at the center of the ion generator 100 due to the positive and negative ions generated through the ion generator 100 and moving through the inside of the duct 10. In order to more stably contact with harmful substances contained in the air to be removed, thereby to more easily remove the harmful substances. For example, when the ion generator 100 is disposed on the right side inside the duct 100, the air purification state on the right side where the ion generator 100 is disposed may be stable, but the ion generator ( This is because the air purification may be relatively unstable as the diffusion of ions decreases in the left region spaced at 100).

An ion generator according to another embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 4, in the ion generator 100, the cation generator 110 and the negative ion generator 120 are alternately spaced apart along the longitudinal center of the duct 10. Here, the cation generator 110 is disposed in front of the anion generator 120, it is preferable that the negative ion generator 120 is disposed behind the cation generator 110.

Because, the bacteria which is one of the harmful substances remaining in the duct 10 has a negative surface charge (-), the cations generated in the cation generator 110 is moved to the surface of the bacteria and the electric shock to the bacteria While causing primary damage to the cells of the bacteria, and the negative ions generated in the negative ion generator 120 is moved to the surface of the bacteria and a negative charge is generated to cause further damage to the cells of the bacteria to prevent the bacteria. This can be effectively removed.

Although not shown in the figure, the ion generator 100 is a plurality of cation generator 110 is spaced apart from each other in the duct 10, the plurality of negative ion generator 120 is spaced apart from the cation generator 110 It may be made to be spaced apart from each other.

For this reason, the inside of the duct 10 may be divided into a cationic region and an anion region along the longitudinal direction, and effectively removes various viruses or bacteria contained in the harmful substances.

A rotating unit according to an embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 5, the rotating unit 200 includes a rotating shaft 210 disposed inside the duct 10 and a supporting member 220 for supporting the rotating shaft 210 in the duct 10. It is composed.

The rotating shaft 210 has a predetermined diameter and length, is installed in the longitudinal direction of the duct 10, and the positive and negative ion generators 110 and 120 are separately installed. The installation direction of the rotating shaft 210 will be described in a vertical direction for convenience of description.

It is preferable that the cation generator 110 is spaced apart from each other along the longitudinal direction of the rotary shaft 210 and does not interfere with the inner surface of the duct 10.

Thrust bearing may be used as the support member 220, but is not limited thereto, and another member capable of stably supporting the load of the cation generator 110 or the anion generator 120 installed on the rotating shaft 210. It is possible to cope with the furnace.

A driving unit according to an embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 5, the driving unit 300 includes a motor 310 having a motor shaft and a power transmission member 320 provided to transmit the rotational force generated by the motor 310 to the rotation shaft. do.

The motor 310 is provided with a bracket (not shown) to be stably supported and fixed to the duct 10, and an electric line (not shown) separate from the electric line for supplying power to the ion generator 100.

The power transmission member 320 is a bevel gear that is commonly used where the rotation shaft 210 and the two shafts arranged in different directions, such as a motor shaft is used, but is not necessarily limited thereto, and the bevel gear Likewise, a power transmission member or gear that can be used where the two axes intersect can be optionally used.

The power transmission member 320 is disposed in parallel to the lower surface of the duct 10, bevel gears are provided at both ends, and a support guide (not shown) for promoting stable rotation of the power transmission member 320 is provided. .

Although not shown in the drawings, the driving unit 300 may be configured such that the motors are provided to individually transmit power to the cation generator 110 and the rotating shaft 210 installed in the negative ion generator 120.

A control unit according to an embodiment of the present invention and components connected to the control unit will be described with reference to the drawings.

Referring to FIG. 6, the control unit 500 receives an on-off operation state of the air conditioner 20 disposed in the building and detection information sensed by the detection unit 400.

The air conditioner 20 includes a first air conditioner provided in a machine room (not shown), a second air conditioner, and an n-th air conditioner, and the air conditioner 20 provides cooling and heating for each floor.

The sensing unit 400 may be installed in a duct installed in each floor, and includes a first sensing unit, a second sensing unit, and an nth sensing unit, and a plurality of sensing units are provided to accurately detect a contamination state in the duct. do.

The control unit 500 receives the operation state information of the air conditioner 20 and the detection information detected by the detection unit 400, the duct management module 40 and the manager terminal 50 through the Internet network 30. To transmit.

The duct management module 40 may provide a control command to the control unit 500 and a display unit 42 for displaying the operation state of the air conditioner 20, the contamination state information of the duct detected by the detection unit 40, and the control unit 500. An input 44, such as a keyboard, is provided for transmission.

The display unit 42 is displayed in green when the pollution state of the duct is less than the reference value, and is displayed in red when the contamination level of the duct is higher than the reference value. Is displayed.

The manager terminal 50 is a mobile phone or smart phone owned by the manager managing the ion generator is used, the text message or alarm is activated on the mobile phone or smart phone.

The control unit 500 selectively controls the operating state of the motor 310 according to the operating state of the air conditioner and the contamination state inside the duct, and the motor 310 is connected to the first motor to rotate the ion generator 100. , The second motor and the nth motor.

The motor 310 is individually controlled by the control unit 500 for the operation of the ion generator 100 installed in a plurality of ducts, the number of revolutions per minute (rpm) of the motor when the degree of contamination inside the duct is above the reference value Is controlled to increase.

The control method of the ion generation device for ducts which concerns on this invention is demonstrated with reference to drawings.

Referring to FIG. 7, (a) an operating state of an air conditioner installed in a building, a pollutant contained in supply air supplied to a duct through the air conditioner, or a harmful substance remaining in the duct Detecting a contamination state of the duct in real time (ST100); (b) transmitting the pollution state information of the duct to a duct management module or a manager terminal (ST200); And (c) the cation and anion generators are operated according to the degree of contamination of the duct, and when the internal pollution state of the duct is higher than a reference value, the cation and anion generator is rotated inside the duct and controlled to purify the inside of the duct. Step ST300 is included.

The pollution state information of the duct detected in step (a) (ST100), the floor-specific information of the building is detected contamination, and the information on a specific section of the duct installed on the floor. For example, when a building has ten floors and ducts are installed in each floor, information on the number and location of floors for the ducts arranged on a specific floor may be sensed.

Step (b) (ST200) is transmitted through the Internet network, the Internet network is used a common communication network installed in the building.

Step (c) (ST300) may be controlled to increase the rotational speed of the cation and anion generator in proportion to the contamination state of the duct. For example, the contamination state inside the duct 10 may be subdivided into a serious contamination state when the pollution level falls below a reference value, when the pollution level exceeds a reference value, and exceeds the reference value.

In step (c), when the air conditioner is in an on state, a voltage applied to the cation and anion generator is applied at a maximum voltage, and when the air conditioner is in an off state, the cation And a voltage applied to the negative ion generator as the average voltage.

The operation state by the duct ion generator according to the present invention configured as described above and the method of controlling the ion generator using the same will be described with reference to the drawings, and the state installed in the building will be described as an example.

Referring to FIG. 8, in the building, air conditioning and heating of the indoor area 60 are made through an air conditioner 20 provided in a machine room (not shown), and the air conditioner 20 is supplied through an outside air intake port. The outside air is sucked and adjusted to a predetermined temperature and humidity that can be discharged to the indoor area 60 and supplied to the duct 10, and supplied to the indoor area 60 through the plurality of outlets 12.

After the outside air is discharged to the indoor area 60, part of the air is recycled to the air conditioner 20 through the plurality of inlets 14 by the suction force by the blower F, and the rest of the outside of the building through the exhaust port. Is discharged.

In the indoor area, a large number of people are living in a long time, the pollutants contained in the outside air can be supplied into the duct 10, the temperature difference or humidity generated in the duct 10 The difference leads to the reproduction of harmful substances such as bacteria or viruses.

The ion generator 100 according to an embodiment of the present invention may be installed in the duct 10 disposed between the air conditioner 20 and the outlet 12, and may be installed at the A position of the drawing. The installation position of the ion generator is according to an embodiment of the present invention, may be installed between the outside air intake port and the air conditioner 20, but is not necessarily limited to the position. In addition, it is noted that a plurality of ion generators 100 may be disposed along the longitudinal direction of the duct 10.

6 or 9, the detector 400 detects an air pollution level inside the duct 10, and transmits the detected information to the controller 500 (ST100). The control unit 500 transmits the inputted information to the Chin management module 40 and the manager terminal 50 through the Internet network 30 (ST200).

The control unit 500 may receive information in real time about the air pollution state of the duct 10 through the detection unit 400, and performs continuous monitoring of the contamination state inside the duct 10, The manager who manages the building periodically provides information on the contamination state of the duct 10.

The control unit 500 receives information about a contamination state input through the first sensing unit spaced along the longitudinal direction of the duct 10, the second sensing unit and the nth sensing unit, and is installed for each floor. The other sensing unit receives information on another floor.

The control unit 500 provides the manager terminal 50 with information about the contamination state of the duct 10 to the manager through a text message, and the information on the current pollution state of the duct 10 is stored in detail in the text message. The file is attached.

The manager can easily check the current state of the pollution state of the duct 10 through a text message transmitted to the manager terminal 50, can recognize the current state of contamination of the duct 10, the control unit 500 In case the manager does not check the information transmitted to the manager terminal 50, the duct management module 40 also transmits information on the current pollution state of the duct 10.

The duct management module 40 displays a contamination state of the duct 10 for all floors of the building through the display unit 42 on which information on each floor of the building is displayed. For example, when the contamination state inside the duct extending to the third-floor A zone is less than the reference value, the duct section of the corresponding floor is displayed in green on the display unit 42, and the duct of the fourth-floor B zone where the contamination has occurred. The interval is marked in red.

The operator or manager immediately recognizes the color information of the section of the duct 10 of the floor displayed through the display unit 42, and controls the control unit through the input unit 44 to purify the duct 10. Is input to the controller 500.

The control signal is transmitted to the control unit 500 through the Internet network 30, and the control unit 500 receives the control signal and applies power to the ion generator 100 to operate the ion generator 100.

The ion generator 100 is operated at the same time the cation generator 110 and the negative ion generator 120 installed on the rotating shaft 210, a large amount of cations and anions through the cation and anion pins 112, 122 at the same time inside the duct 10 While diffusing into space, the inside of the duct 10 is partitioned into a cation region and an anion region.

Referring to FIG. 10, in the duct 10, the pressurized air through the air conditioner 20 or the blower is moved to the place where the cation generator and the anion generator 110, 120 are located, and the first cation generator 110 is generated. Contact with the cation.

In this embodiment, the cation and anion generators 110 and 120 are disposed at the inner center of the duct 10, and are disposed in the longitudinal direction of the duct 10 so that the air and the cations around the cation and anion generators 110 and 120 are disposed. And purification of the air to the negative ion generator (110,120) is made more stable.

More specifically, the surface charge of the bacteria 2 present in the duct 10 is in a negative state, and the positive ions generated in the cation generator 110 have a negative surface charge due to attraction force. Moved to the cell surface and in contact with the negative charge of the bacteria (2), causing damage to the cell surface of the bacteria (2).

The bacterium 2 is damaged to the surface of the cell, is moved to the anion generator 120 via the cation generator 110, the anion diffused through the anion pin 122 of the bacteria (2) The negative ions are moved to the surface and the negative ions are moved and contacted by the attraction force to the cations remaining on the cell surface of the bacteria 2, causing damage to the cell surface of the bacteria 2.

As a result, the bacteria 2 are damaged in the cell membrane, and the bacteria 2 are removed. Thus, the bacteria 2 remain inside the bacteria or ducts 10 contained in the air moving through the inside of the duct 1. Purification is done for large amounts of bacteria.

In the duct 10, after the bacteria in the air moved through the cation generator and the anion generator 110 and 120 are purified, the purified air is discharged to the indoor area 60 through the outlet 12, and the indoor area ( A large amount of in-patients 60) can lead the indoor life in a comfortable state without being exposed to the bacteria (2).

Referring to FIG. 5 or FIG. 11, when the contamination state of the duct 10 exceeds a reference value, the control unit 500 operates together with the cation and anion generators 110 and 120, and the inside of the duct 10. The control signal is transmitted to the motor 310 provided in the driving unit 300 so that the positive and negative ion generators 110 and 120 rotate in step ST300.

The motor 310 is rotated while the motor shaft is maintained at a predetermined speed, the rotational force generated by the motor 310 is transmitted to the power transmission member 320, the power transmission member 320 is provided at both ends The bevel gear is rotated, the bevel gear provided on the rotating shaft 210 is rotated at the same time, the rotating shaft 210 is rotated in the inner space of the duct 10.

The cation and anion generators 110 and 120 may operate in two states in which cations and anions are diffused in a stationary state, and cations and anions are diffused while the cation and anion generators 110 and 120 are rotated. When the generators 110 and 120 rotate and the positive and negative ions are diffused, the purification effect on the bacteria is further improved.

Because, the duct 10 is moved to the air supplied to have a predetermined flow rate, the cation and anion generator (110, 120) is also rotated about the axis of rotation (210) at the end of the cation and anion pin (112, 122) The speed of rotation is generated.

That is, as the speed according to the movement of air and the speed generated at the ends of the cation and anion pins 112 and 122 are added, an ion diffusion region in which ions generated at the cation and anion pins 112 and 122 are diffused is increased, Since nitrogen, oxygen, or carbon dioxide contained in the outside air acts as a medium for diffusing ions, the cation and cation regions in which cations are diffused throughout the entire inner region of the duct 10 are rotated by the cation and anion generators 110 and 120. In addition, an anion region is formed in which anions diffuse.

Due to this, after the bacteria 2 are first contacted with the cations generated in the cation generator 110, the contact is made with the anion diffused through the anion generator 120, thereby purifying.

The controller 500 controls to increase the revolutions per minute of the motor 310 when the contamination state of the duct 10 is greater than or equal to a reference value and when the air conditioner is in an on state. The output voltage applied to the 112 and 122 is also controlled to maintain 1 kV to purify bacteria and viruses remaining in the duct 10.

Although not described in the drawings in this embodiment, the ion generator 100 may be installed and used inside the air conditioning duct (not shown) provided in the vehicle, the operation relationship is similar to that described above, detailed description thereof will be omitted.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10: duct
100: ion generator
110, 120: cation generator, anion generator
112, 122: cation pin, anion pin
200: rotating part
210: rotation axis
300 drive unit
310: motor
320: power transmission member
400: detector
500:

Claims (18)

An ion generator provided inside the duct;
A rotating part provided in the duct, the rotating part allowing an ion generator to rotate;
A driving unit providing rotational force to the rotating unit;
A detector for detecting an air pollution level in the duct; And
And a control unit for controlling the rotational speed of the ion generator and the ion generation amount of the ion generator according to the degree of air pollution in the duct. The method according to claim 1,
The ion generator,
An ion generating device for a duct, characterized in that disposed in either the longitudinal direction or the transverse direction inside the duct. The method according to claim 1,
The ion generator,
It is disposed along the longitudinal direction of the duct, the ion generator for ducts, characterized in that it comprises a cation generator for generating cations, and anion generator for generating anions. The method of claim 3,
The ion generator,
The ion generator for ducts, characterized in that the cation generator and the negative ion generator are alternately spaced apart. The method of claim 3,
The cation generator and anion generator,
Duct ion generator, characterized in that spaced apart from each other in the center along the longitudinal direction inside the duct. The method of claim 3,
The ion generator,
A plurality of cation generators are spaced apart from each other, the cation generator is spaced apart from the ion generator, characterized in that the plurality of negative ion generators are spaced apart from each other. The method of claim 3,
The cation generator and anion generator,
And a cation and anion pin disposed to extend outward, wherein the anion pin has a brush type made of carbon fiber to maximize the discharge area of the anion. The method of claim 7, wherein
Pins of the cation and anion generator,
An ion generator for a duct, characterized by extending in all directions of the cation generator and the anion generator. The method according to claim 1,
The rotation unit includes:
A rotating shaft disposed inside the duct and into which a cation generator and an anion generator are respectively inserted;
Ducts are respectively provided at both ends of the rotation shaft, the ion generating device for ducts, characterized in that it comprises a support member for achieving stable rotation and support of the rotation shaft at the same time. 10. The method of claim 9,
The cation generator and the negative ion generator installed on the rotating shaft,
Duct ion generator, characterized in that spaced apart from each other along the longitudinal direction of the rotating shaft. The method according to claim 1 or 9,
The driving unit includes:
A motor having a motor shaft;
Duct ion generating device comprising a power transmission member provided to transmit the rotational force generated from the motor to the rotating shaft. The method according to claim 1,
The control unit,
When the degree of contamination inside the duct is greater than the reference value, the ion generating device for ducts, characterized in that the control to increase the revolutions per minute (rpm) of the motor. The method according to claim 1,
The ion generator,
Ion generator for ducts, characterized in that installed in the duct installed in the building or the air conditioning duct of the car. (a) the operation state of the air conditioner installed in the building, and the contamination state of the duct by the pollutants contained in the supply air (Supply Air) supplied to the duct (Duct) through the air conditioner or harmful substances remaining in the duct Sensing in real time;
(b) transmitting the pollution state information of the duct to a duct management module or a manager terminal; And
(c) a cation and anion generator is operated according to the degree of contamination of the duct, and if the internal contamination of the duct is higher than a reference value, the cation and anion generator is rotated inside the duct and controlled to purify the inside of the duct Control method of the ion generating device for ducts comprising a. 15. The method of claim 14,
The pollution state information of the duct detected in the step (a),
Control method of the ion generating device for ducts, characterized in that it contains the information on each floor of the building is detected pollution, and information about a specific section of the duct installed on the floor. 15. The method of claim 14,
Step (b), the control method of the ion generating device for ducts, characterized in that transmitted through the Internet. 15. The method of claim 14,
The step (c)
The control method of the ion generating device for ducts, characterized in that controlled to increase the rotational speed of the cation and anion generator in proportion to the contamination state of the duct. 15. The method of claim 14,
The step (c)
When the air conditioner is On, the voltage applied to the cation and anion generator is applied at the maximum voltage,
And a voltage is not applied to the cation and anion generator when the air conditioner is in an off state.

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