JP2001304638A - Generation method and apparatus for air ion - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cause small air ions with positive electric charges and small air ion with substantially equal amount negative electric charges to be generate by making use of a charging phenomenon, occurring in association with following spraying of water. SOLUTION: Static electricity generation means and water removal means are provided. The static electricity generation means is binary fluid nozzles 8a, 8b, 8c incorporated in an ion generator 1, which discharge air ion produced by a charging phenomena associated with spraying of water to produce in air positive charge small air ions with positive electric charges and small air ion with negative electric charges both charges being substantially equal in amount. The water removal means is a cyclone separator, in which water droplets discharged into the air following the production of the small air ion are separated centrifugally and are removed from the air.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for generating substantially equal amounts of small positive ions and small negative ions in the air.

[0002]

2. Description of the Related Art The phenomenon that air ions are generated due to the splitting of water droplets is caused by the Lenard's effect.
It has long been known as t). The Leonard effect is that when a water droplet breaks up in the air, more precisely, when the water droplet collides with a barrier metal plate and breaks up into fine water droplets, negative ions are generated in the air nearby and the water droplets become negative ions. And the same amount of positive charge is obtained. This phenomenon then
Simpson's experiments have shown that a similar effect to Leonard can occur when a water droplet splits only in air.

Simpson has applied the results of this experiment to the explanation of electrical separation in thunderclouds. According to Simpson's experiment, the falling speed of a water drop having a radius of 2.4 mm is 8 m / s.
ec. Since it is not uncommon for the updraft in the thundercloud to be higher than 8 m / sec, water droplets having a radius of 2.5 mm or less cannot fall and are instead carried upward. 2.5m radius
Water droplets of m or more split and are carried upward in the upward airflow, but grow and drop into large water drops on the way, and split again. Due to this repetitive splitting, the previous effect becomes even greater, eventually resulting in the collection of negative charges above the thundercloud and positive charges below. In other words, it becomes a thundercloud of negative polarity (Meteorological Electronics Hatakeyama et al., Iwanami Shoten 195
5 See pages 94-95).

A device for generating negative ions in the air by using the Leonard effect is described in, for example, Japanese Patent Publication No. 5-587555 (Prior Art 1). A miniaturized one for office use is disclosed, for example, in Japanese Utility Model Laid-Open No. 4-126717 (Prior art 2) as an air purifier.

[0005]

As described above, according to the Leonard effect, the idea that negative ions are generated in the air and water droplets obtain the same amount of positive charge as the negative ions has been established. The generation of almost equal amounts of positive and negative ions therein has received little attention. On the other hand, according to the static electricity theory, the Leonard effect is a charging phenomenon caused by spraying water, and small droplets have an excess of negative ions and large droplets have an excess of positive ions due to the structure of the electric double layer. It is described that it is charged in a state (see “Electrostatic Handbook”, pages 104 to 105, published by Ohmsha, edited by the Electrostatics Society of Japan).

According to the apparatus for generating negative ions in the air using the Leonard effect, it is possible to generate abundant negative ions in the air. Therefore, a comfortable space mainly utilizing the physiological action of the negative ions. Have been used in devices for forming In addition, a charge removing device can remove charges from a positively charged object. However, the method cannot be applied to the static elimination processing of a negatively charged object. The object is classified into a positively charged object and a negatively charged object. Therefore, in order to perform the charge elimination process of the charged object, it is basically desirable to blow air containing equal amounts of positively charged ions and negatively charged ions to the charged object.

Here, according to Simpson's experiments and the theory of static electricity, negative ions generated in the air are eventually water droplets, and the size of the water droplets is relative, so that the size of the sprayed water droplets is reduced. If it is possible to generate almost equal amounts of small air ions of positive charge and small air ions of negative charge in the air, the application and development of static electricity removal of charged objects and other technical fields are greatly expected. it can. However, according to the spraying of water, there is a problem that large water droplets are generated accompanying the generation of air ions. Large water droplets are a great enemy for electronic components such as semiconductor devices.
Fortunately, techniques for separating and removing water droplets from the air have already been established in devices that generate negative ions in the air using the Leonard effect, such as in Prior Art Example 1.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method and an apparatus for generating substantially equal amounts of small positive air ions and small negative air ions in air by utilizing a charging phenomenon caused by spraying water. Is to do.

[0009]

In order to achieve the above object, in the method of generating air ions according to the present invention, air ions generated by a charging phenomenon caused by spraying water are released, and substantially equal amounts of air ions are released into the air. It sequentially performs a static electricity generation process that generates small air ions with positive charges and small air ions with negative charges, and a water removal process that removes large water droplets released accompanying the generation of air ions from the air. is there.

[0010] The static electricity generating process is a process in which pressurized water and pressurized air are mixed and released into the air.

The static electricity generation process is a process in which pressurized water and pressurized air are mixed, released into the air from a nozzle, and split into fine water droplets.

The static electricity generation process is a process in which pressurized water and pressurized air are jetted from a nozzle, and then mixed in the air to break up into fine water droplets.

The static electricity generation process is a process for generating friction between water and air by exciting water.

Further, in the air ion generating apparatus according to the present invention, air ions generated by the charging phenomenon associated with the spray of water are released, so that approximately equal amounts of small air ions having positive charges and air having negative charges are introduced into the air. It has static electricity generating means for generating small ions and water removing means for removing water droplets released into the air accompanying the generation of air ions from the air.

The static electricity generating means is a two-fluid nozzle for discharging pressurized water and pressurized air into the air.

The static electricity generating means is an external mixing two-fluid nozzle for discharging pressurized water and pressurized air into the air and mixing them.

Further, the static electricity generating means has an ultrasonic oscillator, and the ultrasonic oscillator vibrates water to generate friction between water and air.

The water removing means is a cyclone separator for extracting small air ions by centrifugally separating water droplets while swirling air containing air ions and water droplets generated by the static electricity generating means.

The small positive air ions and the small negative air ions generated in the air are used for neutralizing a charged object.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS According to the first aspect of the present invention, a static electricity generating process and a water removing process are sequentially performed. The static electricity generation process is a process of releasing air ions generated by a charging phenomenon caused by spraying water to generate approximately equal amounts of small positive air ions and small negative air ions in the air. The treatment is a treatment for removing large water droplets released accompanying the generation of air ions from the air. In the process of generating static electricity, fine water droplets are generated in the air by spraying water. These fine water droplets are charged positively and negatively by friction between water and air.

In the present invention, positively charged fine water droplets are defined as small positive air ions, and negatively charged fine water droplets are defined as negative small air ions. In the present invention, the small amount of positively charged air and the small amount of negatively charged air are substantially equal when the positive / negative ion ratio is 8%.
0% or more. The air that has been subjected to the static electricity generation process has a degree of wetness that wets the paper in an atomized state, but the water removal process removes large water droplets and makes the air transparent, and the air is made of paper, cloth Never get wet.

According to the second aspect of the present invention, the static electricity generating process is a process in which pressurized water and pressurized air are mixed and released into the air. It is considered that the greater the pressure energy, the greater the frictional resistance generated between water and air, and the greater the amount of air ions generated.

According to the literature, regarding the relationship between water and static electricity, if the purity of water is increased, static electricity is easily generated in water, and particularly, the electric conductivity (μS / cm) becomes zero. .
It has been reported that the charging phenomenon becomes remarkable when the level of ultrapure water is in the vicinity of 1 μS / cm or lower (Basic knowledge of new water to know, written by Shoji Kubota, Ohmsha, July 10, 1994) However, in the present invention, even at a drinking water level of several hundred μS / cm, the positive and negative ion amounts as shown in the examples are obtained.

According to the third aspect of the present invention, the static electricity generating process is a process in which pressurized water and pressurized air are mixed, released into the air from a nozzle, and split into fine water droplets. The pressurized water and the pressurized air are jetted from the nozzle in the same direction, and the pressurized water is split and ionized by frictional resistance between them.

In the fourth aspect of the present invention, the static electricity generation treatment is a treatment in which pressurized water and pressurized air are jetted from a nozzle and then mixed in the air to break up into fine water droplets. The pressurized water and the pressurized air are jetted from the nozzle in the same direction, and the pressurized water is split and ionized in the jetted air due to frictional resistance between them. According to the experiment, after mixing the pressurized water and pressurized air, rather than mixing pressurized water and pressurized air immediately after injection from the nozzle to split the pressurized water,
Spraying from the nozzle produced more air ions.

In the fifth aspect of the present invention, the static electricity generating process is a process for generating friction between water and air by exciting water. An ultrasonic oscillator can be used to excite water.

In the sixth aspect of the present invention, the air ion generator comprises a combination of static electricity generating means and water removing means. The static electricity generating means emits air ions generated by a charging phenomenon caused by spraying of water to generate approximately equal amounts of small positive air ions and small negative air ions in the air. The means removes water droplets released into the air accompanying the generation of air ions from the air. From the air ion generator, almost equal amounts of small air ions of positive charge and small air ions of negative charge are generated. In the present invention, the water removing means separates the positively charged water droplets into gas and liquid. , Not
This is a process for removing water droplets large enough to wet paper, cloth, and the like. The amount of positively charged small air ions and negatively charged small air ions in the air that has passed through the water removing means does not immediately decrease significantly. However, the positively charged small air ions and the negatively charged small air ions generated over time recombine and disappear.

In the invention according to claim 7, the static electricity generating means is a two-fluid nozzle for discharging pressurized water and pressurized air into the air. Two-fluid nozzle is also known as air injection nozzle,
Gas-liquid mixed type nozzle, also called air atomizing. By using a two-fluid nozzle, the pressurized water
It becomes fine water droplets charged by flowing friction at the time of ejection.

In the eighth aspect of the present invention, the static electricity generating means is an external mixing two-fluid nozzle for discharging pressurized water and pressurized air into the air and mixing them. The two-fluid nozzle includes an external mixing two-fluid nozzle and an internal mixing two-fluid nozzle. Either nozzle can generate approximately equal amounts of small positive air ions and small negative air ions, but experiments have shown that the amount of air ions generated is of the internal mixed type. Although the fluid nozzle was superior, a very small amount of water droplets were scattered. However, no wetting on the glass plate was observed.

In the ninth aspect of the present invention, the static electricity generating means has an ultrasonic oscillator, and the ultrasonic oscillator vibrates water to generate friction between water and air. In order to release air ions generated by a charging phenomenon associated with spraying water, it is necessary to apply energy to water and air. The method of applying energy is not limited to pressurization but may be vibration. Ultrasonic oscillation can generate fine water droplets charged by flowing friction.

In the tenth aspect of the present invention, the water removing means is a cyclone separator for extracting small air ions by centrifugally separating water droplets while swirling air containing air ions and water droplets generated by the static electricity generating means. . The primary function of the cyclone separator is to separate solids (powder) and gas, but the liquid (water droplets) contained in the air is shaken off in the direction of centrifugal force by the centrifugal force generated by rotation. The fine water droplets removed from the air and entrained in the swirling air are further finely divided into air ions.

In the eleventh aspect of the present invention, the positively charged small air ions and the negatively charged small air ions generated in the air are used for neutralizing a charged object. Small positive and negative air ions generated by the air ion generator of the present invention have a longer lifespan than air ions generated by corona discharge, have a half-life of 400 seconds, and are transported far through an air line. it can. In addition, the mobility is 0.52
Air ions of cm ² / V · sec or more not only remove static electricity of the charged substance but also improve the electric conductivity of the atmosphere.

[0033]

Embodiments of the present invention will be described below.

(Embodiment 1) Referring to FIG. 1, an air ion generator according to the present invention comprises a combination of an ion generator 1, a gas-liquid separator 2, and a water tank 3. The ion generation unit 1 and the gas-liquid separation unit 2 are connected by a connection unit 4, a blower 5 is connected to the input side of the ion generation unit 1, and air is connected to the output side of the gas-liquid separation unit 2. An air ion injection unit 7 is connected via an ion transport unit 6. The ion generating section 1 is a section that generates positive and negative air ions generated in the air due to a charging phenomenon caused by spraying of water. Two-fluid nozzles 8a, 8b, 8c.

An air compressor 9 and a pump 10 are connected to the two-fluid nozzles 8a, 8b and 8c, and pressurized air compressed by the air compressor 9 through an air supply pipe 11 and a jet water supply pipe 12 And the water in the water tank 3 pumped by the pump 10 is supplied through the two-fluid nozzles 8a and 8
From b and 8c, water is sprayed, and air ions generated by the charging phenomenon accompanying the spraying are released to generate almost equal amounts of small positive air ions and small negative air ions in the air.

The gas-liquid separator 2 is a cyclone separator. The cyclone separator receives a swirling flow of air containing air ions generated in the ion generator 1 and is discharged into the air accompanying the generation of air ions. This is a means for removing water droplets from the air. Two-fluid nozzles 8a, 8b,
For 8c, an external mixing type or internal mixing type nozzle is used.

FIG. 2 shows the structure of an external mixing type two-fluid nozzle.
FIG. 4 shows the structure of the internal mixing type two-fluid nozzle (all manufactured by Everloy Co., Ltd.). The external mixing type two-fluid nozzle (internal mixing type two-fluid nozzle) has a nozzle body 13 (1
4) a compressed air passage 15 (16) formed in the cylinder;
It has a water flow path 17 (18) arranged orthogonally to the compressed air flow path 15 (16). In the external mixing type two-fluid nozzle, the nozzle hole of the water flow path 17 and the compressed air flow path 15 In the two-fluid nozzle of the internal mixing type, the water flow path 18 and the compressed air flow path 16 merge in the nozzle body 14 to open a single-hole nozzle.

In the example of FIG. 1, the injection water supply pipe 1
Although the example in which the two-fluid nozzles 8a, 8b, and 8c are provided in three places above and below 2 is shown, the number and arrangement are not limited to this example, and one or a plurality of two-fluid nozzles may be connected to the injection water supply pipe. They may be radially attached to the center of the twelve, or may be attached in series vertically, or may be arranged in combination.

In the embodiment, the water in the water tank 3 is pumped out by the pump 10 and the pressurized water is supplied to the two-fluid nozzles 8a and 8a.
In addition, water is supplied to b, 8c and the air compressor 9 is driven to pressurize the air sucked from the outside, and the pressurized air is supplied to the two-fluid nozzles 8a, 8b, 8c. On the other hand, the blower 5 is driven to suck the outside air to form a swirling flow and send the air to the ion generator 1. From the two-fluid nozzles 8a, 8b, 8c, pressurized water and pressurized air are jetted into the air sent to the ion generator 1. In an external mixing type two-fluid nozzle, pressurized water and pressurized air are released into the air and then mixed. In an internal mixing type two-fluid nozzle, pressurized water and pressurized air are mixed and released into the air. Is done.

In any case, air ions generated by the charging phenomenon associated with the spraying of water are released as a process of generating static electricity, and approximately equal amounts of small positive air ions and small negative air ions are generated in the air. . The swirling flow of the air in the ion generator 1 containing the air ions continues to flow along with the large water droplets discharged accompanying the generation of the air ions.
The water droplets are sent into the cyclone separator, and the water droplets are centrifugally separated while swirling the air containing air ions and water droplets in the cyclone separator.As a water removal process, large water droplets released accompanying the generation of air ions A small amount of positively charged air ions and a substantially negatively charged small air ion are removed from the air and are sent to the outside from the air ion injection unit 7 together with the air.

Using an external mixing two-fluid nozzle and an internal mixing two-fluid nozzle (both manufactured by Everloy Co., Ltd.), the amount of generated air ions was measured under the following experimental conditions. The generated small air ions were measured using an ion counter manufactured by Dan Kagaku Co., Ltd. with the ion mobility set to 0.4 cm ² / V · sec. Table 1 shows the measurement results. 3 and 5
2 shows the relationship between the particle diameter and the number of fine water droplets ejected from the external mixing type two-fluid nozzle and the internal mixing type two-fluid nozzle, respectively. The arithmetic mean water droplet distribution graph shown in the figure is data measured by Everloy Corporation.

[0042]

【table 1】

According to the first embodiment, the amount of positive and negative ions generated from the two-fluid nozzle of the external mixing type and the two-fluid nozzle of the internal mixing type are compared under the same conditions, and the amount of the ion generated by the internal mixing type is compared It can be seen that the two-fluid nozzle is slightly better. However, there was no significant difference in the positive / negative ion ratio.
As is clear from FIGS. 3 and 5, the two-fluid nozzle of the external mixing type has a large number of fine water droplets having a large particle diameter, has a good gas-liquid separation property, and has no water droplet scattering. However, none of the two-fluid nozzles was able to wet the glass plate.

According to the first embodiment, by using the combination of the existing two-fluid nozzle and the cyclone separator, the static electricity generation process and the water removal process are sequentially performed.
Releases air ions generated by the charging phenomenon associated with water spray, generates approximately equal amounts of small air ions of positive charge and small air ions of negative charge in the air. Large water droplets can be removed, and even if the obtained air ions contain fine water droplets as small air ions, the water droplets are small enough not to be visually recognized, and the glass plate Since it does not wet, excellent effects can be obtained when used for static elimination of a charged object.

(Embodiment 2) In Embodiment 2, an ultrasonic generator is used as an electrostatic generator, an electrostatic generator is used to generate static electricity, and the water is vibrated to generate friction between the water and the air. is there. By applying ultrasonic vibrations to the water, the water is vibrated to spray fine water droplets, and due to the charging phenomenon accompanying the spraying, almost equal amounts of small air ions of positive charge in the air,
It emits negative ions and small air ions.

FIG. 6 shows an example in which a combination of a water tank 19 and an ultrasonic oscillator 20 (Ultrasonic humidifier model: AH-141 manufactured by General Corporation) is incorporated in the ion generating section 1. Aquarium 1
9 is supplied with water in a water supply source 22 through a pipe 21, and the water in a water tank 19 is vibrated by an ultrasonic oscillator 20. As a result, approximately equal amounts of small air ions having a positive charge and small air ions having a negative charge are generated in the air, and the air ions are blown into the outside air sucked from the blower 5 and are generated in the gas-liquid separation section 2. The water droplets generated by spraying water as a water removal process while rotating in the gas-liquid separation unit 2 are removed from the drain vent 23, and the air ions pass through the air ion transport unit 6 and the air ion injection unit The air is sent from 7 to the outside. In this example, it was confirmed that the arithmetic average water droplet particle diameter of the fine water droplets generated from the ion generating section 1 was 12 microns. Table 2 shows the amount of small air ions generated and the experimental results of water droplet scattering.

[0047]

[Table 2]

According to the second embodiment, the use of an ultrasonic oscillator in the air ion generating section eliminates the need for air compressors, pumps, and other necessary equipment in the first embodiment, and is therefore relatively compact. Thus, a low-noise air ion generator can be provided, and can be used in industrial fields such as a static eliminator.

In the first and second embodiments, as the purity of the water used is increased to tap water, soft water, distilled water, pure water, and ultrapure water, the amount of small air ions generated increases for both positive ions and negative ions. Showed a trend. In addition, when the charged object was neutralized with the generated small air ions, it was confirmed that the small static ions obtained by the present invention could shorten the neutralization time.

[0050]

As described above, according to the method of the present invention, by sequentially performing the process of generating static electricity and the process of removing water, air ions generated by the charging phenomenon associated with the spray of water are released, and the air is substantially discharged into the air. Equal amount of small air ions with positive charge and small air ions with negative charge can be generated.Large water droplets released accompanying the generation of air ions are removed, and fine water droplets as small air ions are removed. , The water droplets are so small as to be substantially invisible and do not wet the glass plate, so that excellent effects can be obtained when used for static elimination of charged objects.

Further, the device of the present invention comprises:
The static electricity generating process and the water removing process are sequentially performed in combination with a water removing means. The static electricity generating means includes a two-fluid nozzle (an externally-mixed two-fluid nozzle, an internally-mixed two-fluid nozzle). In addition, an ultrasonic oscillator, a so-called ultrasonic humidifier, emits air ions generated by the charging phenomenon associated with the spraying of water, so that approximately equal amounts of small air ions with positive charges and small air particles with negative charges are released into the air. Ions can be generated, and water removal means can use a cyclone separator to separate water droplets in an atomized state to a state in which they cannot be seen at the outlet side. It can supply clear high humidity, clean, clean air.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an air ion generator according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view of an external mixing type two-fluid nozzle used in the first embodiment.

FIG. 3 is a graph showing the distribution of the particle diameter of water jetted by an external mixing type two-fluid nozzle

FIG. 4 is a sectional view of an internal mixing two-fluid nozzle used in the first embodiment.

FIG. 5 is a distribution graph of sprayed water particle diameter by an internal mixing type two-fluid nozzle.

FIG. 6 is a configuration diagram of an air ion generator according to a second embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Ion generation part 2 Gas-liquid separation part 3 Water tank 4 Connection part 5 Blower 6 Air ion conveyance part 7 Air ion injection part 8a Two fluid nozzle 8b Two fluid nozzle 8c Two fluid nozzle 9 Air compressor 10 Pump 11 Air supply pipe 12 Injection water supply pipe 13 External mixing type two-fluid nozzle 14 Internal mixing type two-fluid nozzle 15 Compressed air flow path (External mixing type nozzle) 16 Compressed air flow path (Internal mixing type nozzle) 17 Water flow path (External mixing type nozzle) 18 Water flow path (internal mixing type nozzle) 19 Water tank 20 Ultrasonic transmitter 21 Pipe 22 Water supply source 23 Draining

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) B04C 9/00 B04C 9/00 F term (Reference) 4D032 AC21 AD04 AE10 BA06 BB18 CA10 4D053 AA01 AB01 BA01 BB01 BC01 BD04 CA01 CG05 DA10 4F033 BA04 PD06 QC04 4G075 AA03 BA08 BB05 BD08 BD09 BD13 CA23 DA02

Claims (11)

[Claims] 1. A static electricity generating process for releasing air ions generated by a charging phenomenon associated with spraying of water to generate substantially equal amounts of small positive air ions and small negative air ions in the air. A method for generating air ions, comprising sequentially performing a water removal process of removing large water droplets released accompanying the generation of ions from the air. 2. The method for generating air ions according to claim 1, wherein the static electricity generating process is a process in which pressurized water and pressurized air are mixed and released into the air. 3. The air ion according to claim 1, wherein the static electricity generating process is a process in which pressurized water and pressurized air are mixed and released into the air from a nozzle to split into fine water droplets. How it occurs. 4. The static electricity generating process is a process in which pressurized water and pressurized air are jetted from a nozzle, and then mixed in the air to break up into fine water droplets.
3. The method for generating air ions according to item 1. 5. The air ion generating method according to claim 1, wherein the static electricity generating process is a process of generating friction between water and air by exciting water. 6. A static electricity generating means for releasing air ions generated by a charging phenomenon caused by spraying water to generate substantially equal amounts of small positive air ions and small negative air ions in air, and air. A water removing means for removing, from the air, water droplets discharged into the air accompanying the generation of ions. 7. The air ion generator according to claim 6, wherein the static electricity generating means is a two-fluid nozzle for discharging pressurized water and pressurized air into the air. 8. The air ion generator according to claim 7, wherein the static electricity generating means is an external mixing type two-fluid nozzle for discharging pressurized water and pressurized air into the air and mixing them. . 9. The method according to claim 6, wherein the static electricity generating means has an ultrasonic oscillator, and the ultrasonic oscillator is configured to excite water to generate friction between the water and the air. Air ion generator. 10. The water removing means is a cyclone separator for extracting air small ions by centrifugally separating water drops while swirling air containing air ions and water drops generated by the static electricity generating means. Item 7. An air ion generator according to Item 6. 11. The air according to claim 6, wherein the small air ions having a positive charge and the small ions having a negative charge generated in the air are used for neutralizing a charged object. Ion generator.