KR20200082698A - Ionic Wind Generator - Google Patents

Abstract

The present invention relates to an ion wind generator and provides the ion wind generator, which extends an ionization area to a ring electrode area by additionally providing a ring-shaped ring electrode surrounding the outside of a discharge electrode, so that electric charges can be generated in a wide area, thereby expanding the area of ion wind and accelerating the speed of the ion wind since the amount of charge generated in the ionization area can also be increased, and further increasing the amount of charge generated from the ring electrode by including three ring electrodes and supplying three-phase alternating current to each of the three ring electrodes. Therefore, the speed of the ion wind can be further accelerated.

Description

Ion wind generator

The present invention relates to an ion wind generator. More specifically, by further comprising a ring-shaped ring electrode surrounding the outside of the discharge electrode, the ionization region can be extended to the ring electrode region to generate electric charges in a wide area, thereby expanding the ion wind region, and the ionization region. It is also possible to increase the amount of charge generated in the can further accelerate the speed of the ion wind, by providing three ring electrodes, and supplying three-phase alternating current to each of the three ring electrodes, thereby generating the amount of charge generated from the ring electrodes. The present invention relates to an ion wind generator that can further increase, and thus accelerate the speed of the ion wind.

The ion wind using corona discharge has the advantage of easy generation and control of wind speed, no mechanical movement, no abrasion and noise, and miniaturization.

The ion wind was chattock's quantitative analysis of the phenomenon of the ion wind since Hauksbee discovered in 1719 that a weak wind was generated in the first charged tube, and then was dynamically identified by Robinson. In particular, Robinson proved that the speed of the ionic wind is expressed as a function of current, and that only 1-2% of the electrical energy supplied during corona discharge in the air is converted into kinetic energy of gas particles. Meanwhile, Christenson et al. proposed that ionic winds could be used to propel aircraft.

The principle of the blower using corona discharge is that charges generated by the corona discharge electrode move from the discharge electrode (emitter electrode) to the counter electrode (collector electrode) by the electric field between the electrodes, that is, the Coulomb force. The electric charges moving in this way move air molecules in the same direction through collision with air molecules, and motions of these air molecules gather to be finally used as a blowing force.

Therefore, in order to effectively generate the ionic wind, it is necessary to generate many electric charges by corona discharge and to generate a high applied voltage (electric field) to strongly accelerate these electric charges.

Attempts have been made to develop such an ion wind generator in various forms.

1 is a conceptual diagram conceptually showing the structure of a general ion wind generator according to the prior art.

The general ion wind generator includes a discharge electrode 100 that generates electric charge E1 by corona discharge, and a counter electrode 200 that draws electric charge E1 generated by discharge electrode 100 by electromagnetic force. , The discharge electrode 100 is provided with a high voltage power supply 300 that supplies positive power to the opposite electrode 200 and negative power to the counter electrode 200.

The negative charge E2 generated in the counter electrode 200 is too small to be used as a blowing force that causes wind, and when the positive charge E1 generated in the discharge electrode 100 moves, it may be used as a blowing force due to collision with air. Therefore, in the following, charge is used to mean positive charge.

The discharge electrode 100 is formed in the form of a needle having a tip portion so that corona discharge can be easily generated, and the counter electrode 200 is variously formed according to need, such as a cylindrical or flat plate.

In the region adjacent to the tip of the discharge electrode 100, an ionization region Z1 in which charge E1 is generated is formed, and a flow through which the charge E1 flows to the counter electrode 200 through the ionization region Z1 The region Z2 is formed.

In the ion wind generator, since the discharge electrode 100 is formed in the form of a needle having a tip, there is a problem that the area where the ion wind is generated is very small because charge E1 is intensively generated only around the discharge electrode 100. That is, as shown in FIG. 1, the charge E1 is generated only at a portion adjacent to the tip of the discharge electrode 100, and the generated charge E1 is the opposite electrode (from the tip of the discharge electrode 100). Since it flows along the straight line L toward 200), the ion wind is concentrated only in the center of the straight line L, and in other regions, the ion wind hardly occurs, so there is a limit to various use of the ion wind. .

Domestic Patent Publication No. 10-2015-0050941

The present invention was invented to solve the problems of the prior art, and the object of the present invention is to further include a ring-shaped ring electrode surrounding the outside of the discharge electrode, thereby extending the ionization region to the ring electrode region and charging in a wide region. It is possible to expand the region of the ionic wind by generating, and also to increase the amount of charge generated in the ionization region to provide an ion wind generator that can further accelerate the speed of the ion wind.

Another object of the present invention is to provide three ring electrodes, and by supplying three-phase alternating current to each of the three ring electrodes, it is possible to further increase the amount of charge generated from the ring electrodes, thereby further accelerating the speed of the ion wind. It is to provide an ion wind generator that can be made.

The present invention, the discharge electrode is formed in the form of a needle, connected to the positive electrode power source to generate electric charges by corona discharge; A counter electrode formed in a flat plate shape, positioned on a plane perpendicular to the longitudinal direction of the discharge electrode, and connected to a negative electrode power source to attract electric charges generated by the discharge electrode by electromagnetic force; And formed in a ring shape and disposed on a plane parallel to the plane where the counter electrode is located, surrounds the outer space of the discharge electrode, and is connected to the same anode power source to which the discharge electrode is connected and charged by corona discharge. It includes a ring electrode for generating, a three-phase AC power is connected to the discharge electrode and the ring electrode, the ring electrode is provided with three so that each of the three-phase current is supplied, generated through the discharge electrode and the ring electrode An ion wind generating device is provided in which an ion wind is generated as charge moves to the counter electrode, and an ion wind generation region is expanded by the ring electrode.

At this time, the three ring electrodes may be arranged in a form of concentric circles having different diameters such that the discharge electrodes are located at the center of the ring electrodes.

In addition, the three ring electrodes are arranged to be spaced apart along the longitudinal direction of the discharge electrode, and may be sequentially disposed from a ring electrode having a smaller diameter to a ring electrode having a larger diameter toward the end of the discharge electrode.

According to the present invention, by further comprising a ring-shaped ring electrode surrounding the outside of the discharge electrode, the ionization region can be extended to the ring electrode region to generate electric charges in a wide area to expand the ion wind region, and ionization Since the amount of charge generated in the region can also be increased, there is an effect of further accelerating the speed of the ion wind.

In addition, by providing three ring electrodes and supplying three-phase alternating current to each of the three ring electrodes, it is possible to further increase the amount of charge generated from the ring electrodes, thereby further accelerating the speed of the ion wind. There is.

1 is a conceptual diagram conceptually showing the structure of a general ion wind generator according to the prior art,
2 is a conceptual diagram conceptually showing the structure of an ion wind generator according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, when adding reference numerals to the components of each drawing, it should be noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing the present invention, when it is determined that detailed descriptions of related well-known structures or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

2 is a conceptual diagram conceptually showing the structure of an ion wind generator according to an embodiment of the present invention.

The ion wind generator according to an embodiment of the present invention is a device that can expand the ion wind generation region and accelerate the ion wind, and includes a discharge electrode 100, a counter electrode 200, and a ring electrode 400. Including.

The discharge electrode 100 is formed in the form of a needle having a tip so that corona discharge can be easily generated, and is connected to the anode power of the high voltage power supply 300 to generate electric charge E1 by corona discharge.

In the region adjacent to the tip of the discharge electrode 100, an ionization region Z1 in which charge E1 is generated is formed, and a flow through which the charge E1 flows to the counter electrode 200 through the ionization region Z1 The region Z2 is formed. When the charge E1 moves in the flow region Z2, air molecules move together due to collision with the air molecules, and an ion wind is generated.

The counter electrode 200 is formed in a flat plate shape and is located on a plane perpendicular to the longitudinal direction of the discharge electrode 100 and is connected to the negative power source of the high voltage power supply 300 and generated by the discharge electrode 100 The electric charge E1 is attracted by electromagnetic force.

An ion wind is generated in the process of the electric charge E1 generated in the discharge electrode 100 flowing through the flow region Z2 and moving to the counter electrode 200.

As described in the background art, in the general ion wind generator, the charge E1 is concentrated and flows around the longitudinal straight line L from the tip of the discharge electrode 100 toward the counter electrode 200, so that the ion flows. There is a problem that the wind is concentrated only near the straight line L.

In the present invention, a ring electrode 400 is additionally provided to solve this problem.

The ring electrode 400 is formed in a ring shape and is disposed on a plane parallel to a plane where the counter electrode 200 is located to surround the outer space of the discharge electrode 100, and the positive electrode power source to which the discharge electrode 100 is connected. It is connected to the same anode power source to generate electric charge (E1) by corona discharge.

At this time, three-phase AC power is connected to the discharge electrode 100 and the ring electrode 400, and the ring electrode 400 is provided with three three phase currents, respectively, as shown in FIG.

The three ring electrodes 400 may be arranged in a form of concentric circles having different diameters such that the discharge electrodes 100 are located at the center of the ring electrodes 400.

In addition, the three ring electrodes 400 are arranged to be spaced apart along the longitudinal direction of the discharge electrode 100, and the ring electrode 400 having a larger diameter from the ring electrode 400 having a smaller diameter toward the end of the discharge electrode 100 ) May be sequentially arranged.

According to this structure, as shown in FIG. 2, electric charges E1 are generated not only in the peripheral portion of the discharge electrode 100 but also in the peripheral portions of the three ring electrodes 400, and the discharge electrode 100 and the ring electrode 400 ) In the region between (E1) is generated. Therefore, not only the amount of charge E1 generated in the ionization region Z1 increases, but also the charge generation region expands. That is, the ionization region Z1 is expanded.

Since the charge E1 is generated in a relatively wide area, the charge E1 is generated not only near the straight line L connected from the tip of the discharge electrode 100 but also in the wider area, and thus the flow area Z2. After that, it moves to the counter electrode 200, and accordingly, an ion wind is formed in a wider area. That is, the ionization region Z1 is expanded to expand the ion wind region.

In addition, since the amount of charge generated in the ionization region Z1 is also increased by the ring electrode 400, more electric charges move through the flow region Z2, and accordingly, an ion wind is further accelerated.

Meanwhile, the counter electrode 200 according to an embodiment of the present invention may be formed in a mesh form in which a plurality of voids are formed in the electrode region, and accordingly, the charge E1 moved from the discharge electrode 100 is the counter electrode. In the process of being attached to the 200, air molecules move together and pass through the counter electrode 200 to continue to the opposite side of the counter electrode 200 in the form of an ion wind.

In addition, three ring electrodes 400 are provided, and three-phase currents are respectively supplied to each ring electrode 400, so that more charges are generated by the three ring electrodes 400.

In particular, since AC power is supplied instead of DC power, continuous charge generation is possible, and since three-phase currents having a phase difference of 120° are respectively supplied, the amount of charge generation continuously increases through the three ring electrodes 400. , Compared to the case where there is one ring electrode, the charge generation amount increases more rapidly.

In addition, the three ring electrodes 400 are not located on the same plane, but are located on horizontal surfaces in a direction perpendicular to the longitudinal direction of the discharge electrode 100, but are arranged to be located on different horizontal surfaces, thereby allowing each ring electrode ( 400) is less electrically affected by the rest of the ring electrode 400, the charge generation amount is further increased.

As the amount of charge generated increases, the ion wind increases.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: discharge electrode
200: counter electrode
300: high voltage power supply
400: ring electrode

Claims (3)

A discharge electrode formed in a needle shape and connected to an anode power source to generate electric charges by corona discharge;
A counter electrode formed in a flat plate shape, positioned on a plane perpendicular to the longitudinal direction of the discharge electrode, and connected to a negative electrode power source to attract electric charges generated by the discharge electrode by electromagnetic force; And
It is formed in a ring shape and is disposed on a plane parallel to the plane where the counter electrode is located to surround the outer space of the discharge electrode, and is connected to the same anode power source as the anode power source to which the discharge electrode is connected to discharge electric charges by corona discharge. Generating ring electrode
Including, a three-phase AC power is connected to the discharge electrode and the ring electrode, the ring electrode is provided with three so that each of the three-phase current is supplied,
An ion wind generating device characterized in that an ion wind is generated as the charge generated through the discharge electrode and the ring electrode moves to the counter electrode, and an ion wind generation region is expanded by the ring electrode.
According to claim 1,
The three electrode electrodes are arranged in the form of concentric circles having different diameters such that the discharge electrodes are located at the center of the ring electrode.
According to claim 2,
The three ring electrodes are arranged to be spaced apart along the longitudinal direction of the discharge electrode, and the ion wind generator is characterized in that it is sequentially arranged from a ring electrode having a smaller diameter to a ring electrode having a larger diameter toward the end of the discharge electrode. .

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