JP2001241708A - Anion generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent an anion generator from discharging large waterdrops to the outside. SOLUTION: This anion generator sends sucked external air to a water injection tower 1. The tower 1 is composed of an air course section 11 and a water channel section 12, makes the air sent to the air course section 11 to flow in the section 11 while rotating the air, and generates anions in the air by splitting the water pumped up from a water tank 103 into very fine waterdrops by injecting the water into the rotating air flow. The water channel section 12 returns the excessive water produced in the air course section 11 to the water tank 103 as circulating water and can store a fixed amount of water. The air rotating in the section 11 is sent to a cyclone tower 5 and the water contained in the air is separated from the air in the tower 5 and returned to the water tank 103. The air containing anions is sent to the outside. The surface level of the circulating water stored in the water channel section 12 is isolated from the rotating air flow flowing in the air course section 11 by means of a shield plate 15 so as to inhibit the generation of waterdrops by curled-up air.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a negative ion generator for generating negative ions in the air using the Leonard effect (Taki effect).

[0002]

2. Description of the Related Art In recent years, as health consciousness has increased, attention has been paid to the use of air ions as an added value, as well as for purifying indoor air. Air ions have a clear effect on the efficiency and emotions of our work. In particular, negative ions are said to have the effect of stabilizing the mind and enhancing respiratory functions.

When a water droplet breaks in the air, more precisely, when the water droplet collides with a metal plate as a barrier and breaks into fine water droplets, negative ions are generated in nearby air, and the fine water droplets become negative ions. And the same amount of positive charge is obtained. This phenomenon has long been known as the Lenard's effect. Thereafter, it was found that the effect similar to Leonard could occur simply by the water droplet splitting in the air.
immpson).

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.

FIG. 7 shows a configuration of the second prior art. In FIG. 7, the negative ion generator utilizing the Leonard effect is basically composed of a water splitting unit 101, a gas-liquid separating unit 102, a water tank 10
3 in combination. The water in the water tank 103 is pumped out by the pump 104 and supplied to the water splitting unit 101, and is jetted at a high pressure from the nozzle 105 of the water splitting unit 101, and collides with the inner wall 106 of the cylinder of the water splitting unit 101 to form fine water droplets. And produce negative ions in the air.

On the other hand, the blower 10
Fine water droplets containing negative ions generated in the water splitting unit 101 when the outside air sucked from the air is blown into the water splitting unit 101 are sent to the gas-liquid separating unit 102 by a swirling flow of air, and swirl in the gas-liquid separating unit 102. During the ascent, the gas-liquid separation is performed by the centrifugal force generated by the swirling flow, the water droplets are returned into the water tank 103, and the air containing negative ions is supplied from the air supply port 108 to the outside air.

The basic configuration is exactly the same for a large negative ion generator used in a clean room or the like. In a small negative ion generator, a water splitting unit, a gas-liquid separation unit, and a water tank are integrally assembled, while in a large negative ion generator, a water injection tower that becomes a water splitting unit,
A cyclone tower which is a gas-liquid separation unit is connected by a pipe, and a blower and a water injection tower are connected by a duct.

The water tank is a supply source of water to be supplied to the water splitting section, and collects and circulates most surplus water supplied to the water splitting section and water droplets separated in the gas-liquid separation section. The water tank is connected to the water splitting section, and a certain amount of circulating water is stored in the water splitting section, especially because most of the water supplied to the water splitting section needs to be recovered as circulating water. ing.

[0009]

As the air volume is increased in the above-described configuration, the level of the circulating water accumulated in the water splitting section is affected by the swirling flow of the air blown into the water injection tower. The circulating water in the water splitting part is swirled by the swirling air flow, causing vibrations and undulations caused by the rotational movement. May be blown into the gas-liquid separation section as large water droplets, and may be blown out of the air supply port into the outside air without being subjected to the gas-liquid separation processing.

[0010] The water in the water tank is pumped out of the water tank and supplied to the water splitting unit. In the water splitting unit, the water comes into contact with the air sucked from outside the device, is returned to the water tank again, and is used repeatedly. Dust, bacteria,
Filamentous fungi, spores and the like are taken into the circulating water in the water tank.

Therefore, when large water droplets are blown out of the apparatus without being treated in the gas-liquid separation section, the dust, bacteria, filamentous fungi, spores and the like contained in the circulating water are also discharged to the outside of the apparatus together with the water droplets. There is a risk of being blown out.

In the negative ion generator, the water in the water tank is replaced by measures such as overflow and drainage. Dust, bacteria, fungi, spores and the like in the water are removed from the water in the water tank. It should be removed from the aquarium by drainage, and the circulating water should not be released directly to the outside as water droplets.

An object of the present invention is to provide a negative ion generator in which circulating water in a water splitting section is prevented from being swirled by a swirling flow of air, and the circulating water is not discharged to the outside of the apparatus as large water droplets. It is in.

[0014]

Means for Solving the Problems In order to solve the above-mentioned object, the negative ion generator according to the present invention has waving holding means, pumps out water in a water tank, and transfers the pumped water to a water splitting section. It is a negative ion generator that sends water, splits it into fine water droplets at a water splitting unit, blows it to a gas-liquid separation unit to separate fine water droplets, and generates negative ions in the air. , A surge of water in the water channel section stored at the bottom of the water splitting section can be suppressed, and a negative ion generator capable of preventing water droplets from scattering from the water surface can be obtained.

Further, the inside of the water splitting section is divided into an air passage section and a water passage section below the water passage section, and the air passage section turns the water pumped out of the water tank into a swirl of the air sucked from outside the apparatus. The part that breaks into fine water droplets in the flow, the water path part is a part that receives the water supplied in the air path part, circulates the received water back to the water tank, and stores circulating water, As a result, a negative ion generator capable of isolating the air passage and the water passage can be obtained.

The inside of the water splitting section is divided into an air passage section and a water passage section below the water passage section, and the air passage section turns the water pumped from the water tank into a swirl of the air sucked from outside the apparatus. It is a part that breaks up into fine water droplets in the flow, the water channel part is a part that receives the water supplied in the air path part and circulates it back to the water tank, the circulating water is stored, and the ripple holding means is in the water path part A negative ion generator capable of forming a weir inserted to prevent rotation of the surface of the circulating water accumulated at the bottom is obtained.

A negative ion generator having a blower, a water injection tower, a cyclone tower, and a shielding plate,
The blower blows air sucked from the outside of the device to the water injection tower, and the water injection tower forms a water splitting section, and has an air path section and a water path section. The air sent from the blower is swirled to make the inside flow, and the water pumped out of the water tank is injected from the nozzle during the swirling flow of the air,
It is a part that collides with the inner surface of the water jet tower to break it into fine water droplets and generates negative ions in the air, and the waterway part is a part that returns excess water generated in the airway part to the water tank as circulating water. A certain amount of circulating water is stored, the cyclone tower forms a gas-liquid separation part, separates the air sent from the water injection tower into gas and liquid, sends out the air containing negative ions to the outside of the device, and separates The returned water is to be returned to the water tank, and the shielding plate is a wave-holding means, which floats on the surface of the circulating water stored in the water channel portion of the water injection tower, from the swirling flow of air flowing in the water injection tower. A negative ion generator capable of isolating the surface of the circulating water is obtained.

A negative ion generator having a blower, a water injection tower, a cyclone tower, and a swirl prevention plate, wherein the blower blows air sucked from outside the device to the water injection tower. The water jet tower forms a water splitting section, has an air path section and a water path section, and the air path section causes the air sent from the blower to swirl and the inside to flow, and the air The water that is pumped out of the water tank during the swirling flow is jetted from the nozzle, collides with the inner surface of the water jet tower, breaks up into fine water droplets, and generates negative ions in the air. This is a part where excess water generated in the part is returned to the water tank as circulating water, a fixed amount of circulating water is stored, the cyclone tower forms a gas-liquid separation part, and the air sent from the water injection tower is Separate and send air containing negative ions to the outside of the device to separate the separated water. The rotation-preventing plate is a waving holding means, which is combined radially with the flat plates standing upright, and the upper part of each flat plate protrudes upward from the surface of the circulating water and is held in place. As a result, a negative ion generator can be obtained which is inserted into the circulating water in the water channel and can prevent the rotation of the water surface due to the swirling flow of the air acting on the water surface of the circulating water.

The shield / turn prevention plate is a combination of a shield plate and a turn prevention plate, and separates the water channel from the air channel and rotates the circulating water in the water channel at the same time. A negative ion generator capable of inhibiting movement is obtained.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 of the present invention has a waving holding means, pumps water in a water tank, sends the pumped water to a water splitting section, and sends the water to the water splitting section. Split into fine water droplets, blown to the gas-liquid separation part to separate fine water droplets,
A negative ion generator for generating negative ions in the air, wherein the wave holding means can suppress the wave of water accumulated in the bottom of the water splitting part through the water tank, and the scattering of water droplets from the water surface Has the effect of preventing

According to a second aspect of the present invention, the inside of the water splitting section is divided into an air path section and a water path section below the air path section, and the air path section uses water pumped out of the water tank to remove water. In the swirling flow of air sucked from the outside of the air, it is divided into fine water droplets, and the water channel portion receives the water supplied in the air channel portion, returns the received water to the water tank, and circulates the water. Water is stored therein, and the air passage and the water passage can be substantially isolated from each other by a wave-holding means.

According to a third aspect of the present invention, the inside of the water splitting section is divided into an air passage section and a water passage section below the water passage section. Is a part that breaks up into fine water droplets in the swirling flow of air sucked from the outside, and the water path part is a part that circulates the water supplied in the air path part back to the receiving water tank and stores the circulating water. ,
The undulating holding means is formed in a weir inserted into the water channel portion to prevent the rotational movement of the water surface of the circulating water accumulated at the bottom, and has an effect of preventing water droplets from scattering from the water surface by the undulating holding means. Have.

According to a fourth aspect of the present invention, there is provided a negative ion generator having a blower, a water injection tower, a cyclone tower, and a shielding plate, wherein the blower blows air sucked from outside the device. Air is supplied to the water injection tower, the water injection tower forms a water splitting section, has an air path section and a water path section, and the air path section turns the inside while turning the air sent from the blower. It is a part that injects the water pumped out of the water tank into the swirling flow of air from the nozzle, collides with the inner surface of the water injection tower, breaks it into fine water droplets, and generates negative ions in the air, The water channel part is a part where excess water generated in the air path part is returned to the water tank as circulating water, a fixed amount of circulating water is stored, the cyclone tower forms a gas-liquid separation part, and is sent from the water injection tower. The separated air is separated into gas and liquid, and the air containing negative ions is sent out of the device. The separated water is returned to the water tank, and the shielding plate is a waving holding means, which floats on the surface of the circulating water stored in the water channel portion of the water injection tower, and the swirling flow of air flowing in the water injection tower. Has the effect of isolating the surface of the circulating water from the water.

According to a fifth aspect of the present invention, there is provided a negative ion generator having a blower, a water injection tower, a cyclone tower and a swirl prevention plate, wherein the blower blows air sucked from outside the device. The air is supplied to the water injection tower, the water injection tower forms a water splitting section, has an air path section and a water path section, and the air path section turns the air sent from the blower while turning inside. This is the part that injects water pumped out of the water tank into the swirling flow of air from the nozzle, collides with the inner surface of the water jet tower, breaks up into fine water droplets, and generates negative ions in the air. The water channel section is a portion where excess water generated in the air channel section is returned to the water tank as circulating water, a fixed amount of circulating water is stored, the cyclone tower forms a gas-liquid separation section, and the water injection tower is The sent air is separated into gas and liquid, and the air containing negative ions is sent outside the equipment. And, returning the separated water in the water tank,
The anti-rotation plate is a waving holding means, which is radially combined with the flat plates in an upright position, the upper part of each flat plate protrudes upward from the surface of the circulating water, and is held at a fixed position to maintain the circulating water in the channel. And the rotation of the water surface due to the swirling flow of air acting on the water surface of the circulating water can be prevented.

Further, the invention according to claim 6 has a shielding / turning prevention plate which is a combination of a shielding plate and a turning prevention plate, and separates the waterway from the air passage and simultaneously circulates water in the waterway. It has the effect of preventing rotational movement.

[0026]

(Embodiment 1) An embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, the negative ion generator includes a water splitting unit 101, a blower 107, and a gas-liquid separating unit 1.
02 and the water tank 103.

The water splitting portion 101 is a portion for jetting water pumped from the water tank 103 to split the water into fine water droplets. In this embodiment, a number of nozzles 105 for jetting water into the water jet tower 1. A water injection pipe 2 provided with
The water injection pipe 2 is connected to the water tank 103 via the pump 104.

That is, the water injection tower 1 includes the water splitting section 101
The outer cylinder 3 is connected to the blower 107, and the inner cylinder 4 is connected to the cyclone tower 5. The blower 107 sucks outside air from the outside of the device and blows it into the water injection tower 1 to form a swirling flow of air in the water injection tower 1 and blows the air to the cyclone tower 5. Is connected to the upper part of the outer cylinder 3 of the water injection tower 1.

The cyclone tower 5 forms the gas-liquid separation unit 102, receives fine water droplets generated in the water splitting unit 101 together with the swirling flow of air, and performs gas-liquid separation by centrifugal force generated by the swirling of air. And discharges air containing negative ions generated by the splitting of the water droplets to the outside of the apparatus.

In this embodiment, the cyclone tower 5
And the inner cylinder 4 of the water injection tower 1 are connected by a duct 6. The inner cylinder 4 is vertically piped at the center of the outer cylinder 3 of the water injection tower 1, and has a header 7 projecting in the circumferential direction.
The water injection pipe 2 is provided concentrically on the header 7 by standing up and having a large number of nozzles 105 facing the inner surface of the outer cylinder 3.

The opening position of the lower end of the inner cylinder 4 is
The height is set so that the water droplets injected from 05 do not directly enter. The water tank 103 is a tank for filling the water to be sent to the water injection pipe 2. The water tank 103 is provided with an overflow port 8, which is constantly supplied with water from a water supply port (not shown) to maintain a constant water level. I have. In the water tank 103, surplus water generated in the water injection tower 1 and separated in the cyclone tower 5 is supplied to the water injection tower 1 and recovered.

The water tank 103 and the bottom of the cyclone tower 5
The drain 103 is connected to the water tank 103 and the water injection tower 1 through a pipe 10. For this reason, the water filled in the water tank 103 circulates inside the machine, and a part of the circulated water flows into the water jet tower 1 and is stored therein.

As a result, the upper part of the water injection tower 1 becomes the upper air passage part 11 for flowing air,
The channel portion 12 is filled with the circulating water, that is, the water splitting portion 101 is divided into an air channel portion 11 and a water channel portion 12.

In this embodiment, the air sucked from the outside of the apparatus by driving the blower 107 descends while turning along the inner surface of the outer cylinder 3 of the water injection tower 1 from the suction port 13 of the water injection pipe 2. I do. On the other hand, the water in the water tank 103 is pumped out by the pump 104, is injected from each nozzle 105 of the water injection pipe 2, collides with the inner surface of the outer cylinder 3 and splits into fine water droplets. It comes into contact with the descending airflow while circling inside, generating negative ions in the air. Most of the water droplets ejected from the nozzle 105 are directly transmitted along the inner surface of the outer cylinder, fall into the water channel portion 12, are returned into the water tank 103, and are circulated.

The negative ions generated in the water splitting section 101 are placed in a swirling flow of air together with fine water droplets, inverted at the water surface of the water channel section 12 and flow into the inner cylinder 4, and further, into the cyclone tower 5.
By the centrifugal force generated by the rotation while descending while swirling in the cyclone tower 5, the fine water droplets in the swirling air and the fine dust contained in the air are centrifugally separated, and the water droplets are The clean air containing the negative ions returned to the water tank 103 along the inner wall of the cyclone tower 5 together with the dust,
It is reversed and discharged from the air supply port 108 of the cyclone tower 5 to the outside of the apparatus.

In this embodiment, a swirling flow of air descending down the air passage 11 and rising upward into the inner cylinder 4 is blown onto the water surface WL of the circulating water stored in the water passage 12.
According to the present invention, the waving press means 14 is provided on the surface WL of the circulating water on which the swirling flow of air acts to prevent the waving of the water surface WL of the water channel portion 12 due to the effect of the swirling flow of air.

Referring to FIG. 2, in this embodiment, a disk-shaped shielding plate 15 is used for the wave-holding means 14, and the shielding plate 15 is floated on the water surface WL of the water passage portion 12 to separate the air passage portion 11 and the water passage portion 12 from each other. Substantially isolated. The shielding plate 15 not only floats on the water surface WL, but also is located above the circulating water accumulated at the bottom of the water splitting portion 101, and the air passage portion 11 and the water passage portion 1.
2 can be substantially isolated, but if the distance between the bottom of the inner cylinder 4 of the water injection tower 1 and the shielding plate 15 is reduced, the pressure loss of the air inside the water injection tower 1 is correspondingly reduced. And the amount of air blown out from the air supply port 108 of the cyclone tower 5, that is, the amount of air of the negative ion generator decreases.

Conversely, when the distance between the opening edge of the inner cylinder 4 of the water injection tower 1 and the shielding plate 15 is increased, the water injection tower 1
And the size of the apparatus increases, which causes an increase in cost. Further, turbulence occurs between the bottom surface of the inner cylinder 4 of the water injection tower 1 and the shielding plate 15, and the water splitting section 1
01 has a high pressure loss. For this reason, the distance between the lower end of the inner cylinder 4 of the water injection tower 1 and the shielding plate 15, that is, the distance between the water surface WL of the circulating water accumulated at the lower part of the water injection tower 1 and the inner cylinder 4 of the water injection tower 1 Is the internal pressure of the water injection tower 1 0.00
At the time of 5 kgf / cm ² , the thickness is preferably about 100 to 150 mm.

It is desirable that the shielding plate 15 covers the surface of the circulating water accumulated in the water channel portion 12 as much as possible in order to reduce the influence of the air swirling flow of the air channel portion 11 on the water channel portion 12. When circulation of the circulating water between the section 11 and the channel section 12 is impeded, the circulating water injected from the nozzle 105 is transferred to the channel section 1.
2 and cannot be guided to the water tank 103. For this reason, it is necessary to secure a gap between the shielding plate 15 and the inner surface of the outer cylinder 3 of the water injection tower 1 to such an extent that circulation of circulating water is not hindered.

The circulating water injected from the nozzle 105 passes through the gap, is guided to the water channel section 12, and is returned to the water tank 103. With this configuration, in this embodiment, the swirling flow of the air blown into the water splitting unit 101 from the blower 107 descends in the outer cylinder 3, collides with the shielding plate 15, and reversely ascends. Even if it rotates, the shielding plate 1
5, the influence on the circulating water is cut off, and the water surface WL of the circulating water does not undulate, so that the water droplets do not scatter.

As described above, in the embodiment, a disk-shaped plate is used as the shielding plate 15, or the shielding plate 15a
As shown in the figure, the disk may have a conical shape in which the center protrudes. If a conical disk is used for the waving control means 14, the circulating water dropped from the nozzle 105 can be guided by the inclined surface 16 of the cone and easily guided to the water channel section 12.

Alternatively, as shown in FIG. 4, the same effect can be obtained by using a shielding plate 15b having a conical shape with a concave center and having a hole 17 at the center.

In the above embodiment, the air passage section 11 formed in the water jet tower 1 as the water splitting section 101 and the water passage section 1
This is an example of preventing the water surface WL of the circulating water in the water channel portion 12 from waving by isolating the two by the wave holding means 14. To prevent the water surface WL of the water channel portion 12 from waving,
Even if the swirling flow of air acts on the water surface WL of the water channel portion 12 without separating the air channel portion 11 and the water channel portion 12, if the rotational movement of the water surface WL can be substantially suppressed, the water surface Is prevented from occurring, and the generation of vibration can be eliminated.

(Embodiment 2) FIG.
In this example, a turning prevention plate 18 is used. Rotation prevention plate 18
As shown in FIG. 5B, the flat plate 19 is combined radially (crosswise) with the flat plate 19 standing upright. As shown in FIG. 5A, the turning prevention plate 18 is connected to the water channel 1 of the water injection tower 1.
2 and the upper part of each flat plate 19 is protruded from the water surface WL of the circulating water to the air passage section 11 and fixedly held at a fixed position, and the rotation preventing plate 18 passes through the center of the water jet tower 1. , Disposed at a position in contact with the inner surface of the outer cylinder 3,
The water surface WL of the circulating water in 2 is opened to the air passage 11,
Even if the swirling flow of the air flowing in the air passage portion 11 acts on the water surface WL of the water passage portion 12, the plate surface of the flat plate 19 becomes a weir and the water surface W
The rotational movement of L is prevented, so that no ripple occurs,
Also, no vibration sound is emitted.

In this embodiment, the rotation preventing plate 18 is a combination of cross plates, but may be a flat plate or a combination of a plurality of plates.

(Embodiment 3) FIGS. 6 (a) and 6 (b) show a shielding / mounting plate in which a shielding plate 15 is further attached to the upper end of a turning prevention plate 18. FIG.
This is an example in which the turning prevention plate 20 is used as a waving holding means. According to this example, the air passage portion 11 and the water passage portion 12 are isolated by the shielding plate 15, and the rotation of the circulating water stored in the water passage portion 12 is suppressed by the turning prevention plate 18, Even if the surface of the circulating water in the waterway section 12 violently hits the turning prevention plate 18 and water droplets scatter,
The amount of the water droplets hitting the back surface of the shielding plate 15 and jumping back to the air passage portion 11 is greatly reduced, and the ripples on the water surface WL can be more completely suppressed.

[0047]

As described above, according to the present invention, it is possible to prevent the water from flowing into the water tank and accumulating at the bottom of the water splitting part in the water channel and to prevent water droplets from scattering from the water surface. The effect of suppressing the scattering of large water droplets from the liquid separating section to the outside of the apparatus, and also suppressing the generation of vibration or noise of the entire apparatus due to the rotational movement and waving of the water surface can be obtained.

[Brief description of the drawings]

FIG. 1A is a cross-sectional view showing a negative ion generator according to a first embodiment of the present invention. FIG. 1B is a cross-sectional plan view of a main part.

FIG. 2 is an enlarged sectional view of a water injection tower to which a shielding plate is applied.

FIG. 3 is a diagram showing another embodiment of a shielding plate.

FIG. 4 is a view showing still another embodiment of the shielding plate.

FIG. 5A is a view showing a water injection tower of a negative ion generator according to a second embodiment of the present invention. FIG. 5B is a view showing a turning prevention plate.

FIG. 6A is a view showing a water injection tower of a negative ion generator according to a third embodiment of the present invention. FIG. 6B is a view showing a turning prevention plate.

FIG. 7 is a diagram showing an example of a conventional negative ion generator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Water injection tower 5 Cyclone tower 11 Wind path part 12 Water path part 14 Ripple holding means 15 Shielding plate 18 Rotation prevention plate 20 Shielding / rotation prevention plate 101 Water splitting part 102 Gas-liquid separation part 103 Water tank 105 Nozzle 107 Blower

Claims (6)

[Claims] 1. A water splitting unit for splitting water pumped out of a water tank into fine water droplets, and a gas-liquid separating unit for separating fine water droplets blown from the water splitting unit from the air. In a negative ion generator for generating negative ions generated in the air in the air, the water is prevented from splashing from the surface of the water by suppressing the ripples of water flowing into the water tank and remaining at the bottom of the water splitting portion. A negative ion generator, comprising a waving presser. 2. A water splitting section which splits water pumped out of the water tank into fine water droplets in an air flow sucked from outside the device, and a water splitting section below the air duct. Is a portion that circulates the water supplied into the air passage portion back to the water tank and is divided into a water passage portion in which a certain amount of circulating water is stored, and the waving presser means is provided with the air passage portion and 2. The negative ion generator according to claim 1, wherein the water channel is isolated. 3. A water splitting portion, which is a portion for splitting water pumped out of the water tank into fine water droplets in a swirling air flow sucked from the outside of the device, and a portion below the air duct. Is a portion that circulates the water supplied into the air passage portion back to the water tank and is divided into a water passage portion in which a fixed amount of circulating water is stored, and a waving holding means is provided in the water passage portion. The negative ion generator according to claim 1 or 2, wherein a weir is formed to prevent rotational movement of the surface of the circulating water inserted and stored at the bottom. 4. A negative ion generator having a blower, a water injection tower, and a cyclone tower, wherein the blower blows air sucked from outside the device to the water injection tower, The injection tower forms a water splitting section and has an air path section and a water path section, and the air path section flows through the inside while turning the air sent from the blower and flows from the water tank during the swirling flow of the air. The pumped water is ejected from a nozzle and collides with the inner surface of the water jet tower to split into fine water droplets to generate negative ions in the air.The water passage portion is a surplus generated in the air passage portion. Is a part where the water is returned to the water tank as circulating water, and a certain amount of circulating water is stored. Air containing air was sent out of the device and separated The water is returned to the water tank, and the waving holding means floats on the surface of the circulating water stored in the water passage portion of the water injection tower, and the circulating water flows from the swirling flow of air flowing in the water injection tower. The negative ion generator according to claim 1, further comprising a shielding plate for isolating a water surface. 5. A negative ion generator having a blower, a water injection tower, and a cyclone tower, wherein the blower blows air sucked from outside the device to the water injection tower, and The injection tower forms a water splitting section and has an air path section and a water path section, and the air path section flows through the inside while turning the air sent from the blower and flows from the water tank during the swirling flow of the air. The pumped water is ejected from a nozzle and collides with the inner surface of the water jet tower to split into fine water droplets to generate negative ions in the air.The water passage portion is a surplus generated in the air passage portion. A part of the water is returned to the water tank as circulating water, and a certain amount of circulating water is stored therein.The cyclone tower forms a gas-liquid separation part, and separates the air sent from the water injection tower into a gas and a liquid to form a negative ion. Air containing air was sent out of the device and separated In a configuration in which water is returned to the water tank,
The anti-rotation plate is a wavy holding means, and is radially combined with the flat plate in an upright posture, and the upper part of each flat plate is projected upward from the surface of the circulating water, and is held in a fixed position to hold the circulating water in the channel. 2. The negative ion generator according to claim 1, wherein the rotation of the water surface caused by the swirling flow of the air acting on the water surface of the circulating water is prevented. 6. A shielding / turning prevention plate which is a combination of a shielding plate and a turning prevention plate which isolates the waterway from the airflow and at the same time prevents rotation of the circulating water in the waterway. The negative ion generator according to claim 4 or 5, wherein