JPH08215309A - Negative ion generator - Google Patents

Abstract

PURPOSE: To make it possible to separate fine water drops during pneumatic transportation and to supply air contg. negative ions by constituting a negative ion generator in such a manner that the fine water drop-contg. gas generated in a casing repeats collision against separating plates while flowing in a steam separating section to generate the negative ions in the air and that moisture is separated. CONSTITUTION: The water ejected out of a nozzle 9 splits by colliding against a partition wall 10 and a baffle 11 and fills the inside of a water splitting section 2 with the split water drops. The greater part of the water drops fall along the partition wall 10. On the other hand, the outdoor air blows down out of a gas feed port 5 and accelerates the splitting of the water drops, thereby generating a large amt. of the negative ions in the air. The fine water drop-contg. air is throttled by the weir 12 of the partition wall 10 and is increased in velocity of flow at the time when the air emerges from the water splitting section 2. The air collides against a drain pan 14 in an inverting section 4 and separates the water drops. Further, the air enters the steam separating section 3 and repeats the collision against the separating plates 13 and the partition wall 10 or the inside wall of a casing 1, thereby separating the water drops. The air is discharged as negative ion air from a gas delivery port 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for generating negative ions by utilizing the Leonard effect.

[0002]

2. Description of the Related Art Phenomena in which nearby air is ionized when water droplets are divided in association with rain and other precipitation have long been known as the Lennard effect. Leonard is that when water droplets collide with a metal plate and split, ions are generated in the nearby air, and the total amount of charge of the split water droplets is larger than the electric quantity of the first water droplet. It was experimentally found that the total charge of the ions generated at the same time and the electric quantity of the water droplet increased by the splitting are equal, but then Simpson repeated the Leonard's experiment and installed a more precise device. Measured using
The same result as Leonard can occur just by splitting the water droplets in the air, the ions generated in the air are negative ions regardless of the charge of the water droplets, and the water droplets are the same as those generated during the splitting. We have confirmed that we obtain an equal amount of positive charge and reported this (see Meteorology and Electrical Engineering, Hisao Hatakeyama, Minoru Kawano, Iwanami Shoten p.26-27).

Negative ions generated by the ionization of electricity are
In addition to the effects on humans and animals, deodorization, dust removal, bactericidal promotion effect,
Recently, negative ions have come to the spotlight due to their antistatic effect. With regard to the effects on humans and animals in particular, psychological sedative action, hypnotic action, fatigue prevention, fatigue recovery action, analgesic action, diuretic action, bronchial asthma, chronic bronchitis, cold relieving action, refreshing effect, animal rearing It has been experimentally proved that there is a performance improving effect, and attempts to use a negative ion generator in an air conditioning system in order to utilize such a function of negative ions are now being actively made. As a typical method for artificially generating negative ions, a method using corona discharge has been known. In this method, out of positive and negative ions generated by corona discharge, positive ions are captured and negative ions are extracted to the outside. However, this method has a drawback that ozone, nitrogen oxides, etc., which are harmful to the human body, are generated as by-products. In this respect, according to the Leonard effect, since only water droplets are divided, negative ions can be generated without generating harmful components.

A method of generating negative ions by utilizing the Leonard effect is described in, for example, Japanese Unexamined Patent Publication No. 4-141179 (anion production method and apparatus). In short, the method described in this prior example generates fine water droplets from water in a fine water droplet manufacturing machine, and at the same time, blows air at a wind speed of 0.5 to 50 m / sec into the fine water droplets to form fine water droplet mixed air, Then, this fine water droplet mixed air is passed through a separator to separate fine water droplets having a particle size of at least 1 μm into ultrafine water droplet mixed air, and 1 m ^{3 of the} ultrafine water droplet mixed air contains anions (negative ions). 1.25x
10 ⁹ or more are generated.

According to this prior art example, a rotating disk or an impeller is used in a machine for producing fine water droplets, and high-pressure water is jetted into this to break the water into fine water droplets. In this precedent,
An example of using an ultrasonic humidifier as a machine for producing fine water droplets is also described, but in short, when energy is applied to water and it collides with a metal plate, it splits into fine water droplets and negative ions are generated in the air in the vicinity. It seems that this is a faithful reproduction of the Leonard effect.

On the other hand, a cyclone separator is used as a separator for performing gas-liquid separation. Cyclone separator improves the separation performance by increasing the wind speed, and the particle size is 1
It is possible to separate gas and liquid at the level of μm. Moreover, if a cyclone separator is used for the gas-liquid separator, it is possible to spray a water flow on the inner wall of the body of the cyclone separator to break it up into fine water droplets, and combine the functions of the generation of fine water droplets and gas-liquid separation. It is possible to obtain a large amount of negative ions by applying a strong centrifugal force to the water droplets.

[0007]

However, since the cyclone separator performs the gas-liquid separation by utilizing the centrifugal force action of the swirling flow of the high-pressure air flow, it requires high energy for the gas-liquid separation. Yes, a high-power blower is required, and a certain length must be secured in the body of the cyclone for centrifugal separation of gas and liquid. This is a great limitation in downsizing the negative ion generator.

It is true that the cyclone separator is excellent in gas-liquid separation performance and is suitable as a separator for separating water droplets from the gas to take out negative ions, but a small negative ion to be installed in the office or the room of a general household. Incorporating a cyclone separator into the generator is not always effective.
However, it is necessary to remove the fine water droplets contained in the gas, but the gas-liquid separation is not necessarily inevitable by centrifugation.

An object of the present invention is to provide a negative ion generator for separating fine water droplets generated in the air during aerodynamic transport and supplying air containing negative ions without incorporating a cyclone separator in the separator. To do.

[0010]

To achieve the above object, the negative ion generator according to the present invention is a negative ion generator having a water splitting section and a gas-liquid separating section,
The water splitting portion and the gas-liquid separating portion are portions formed along the flow passage of the gas that is pressed in from the outside, and the water splitting portion is formed in the preceding stage of the flow passage of the gas that is sent in from the outside. The nozzle has a nozzle and a partition, and the nozzle ejects water into the water splitting section. The partition collides the water ejected from the nozzle to break it into fine water droplets. Is formed in the latter stage of the gas flow passage and has a separation plate, and the separation plate is arranged so as to project into the gas flow path, forms a gas collision surface, and removes the water contained in the gas from the plate surface. The water in the gas that is captured in and sent to the outside is removed.

The water splitting section forms a gas flow path that allows the gas to flow from the upper side to the lower side, and the gas-liquid separation section forms a gas flow path that allows the gas to flow from the lower side to the upper side. An inversion part is formed between the part and the gas-liquid separation part, and the inversion part is
It is a part that reverses the flow direction of the gas sent from the water splitting part and introduces it into the gas-liquid separation part.

Further, the water splitting section and the gas-liquid separating section are formed in parallel by partitioning the inside of the casing, and the lower space in the casing for communicating the water splitting section and the gas-liquid separating section is inverted. To form a part.

Further, the water splitting section and the gas-liquid separating section are partitioned by a partition in the casing, and the surface of the partition on the water dividing section side serves as a screen for colliding the water ejected from the nozzle, and the gas-liquid separating section side. The surface of the partition wall serves as a separation plate that traps water contained in the gas.

Further, the lower end of the partition wall overhangs toward the water splitting portion to form a weir, and the weir reduces the outflow cross-sectional area of the gas flowing out of the water splitting portion to increase the flow velocity of the outflowing gas. .

[0015]

In the present invention, water is jetted in the gas flowing into the water splitting portion of the casing, the water collides with the partition in the water splitting portion and is divided into fine water droplets to generate negative ions in the air. , The gas containing fine water droplets folds back inside the casing and repeatedly collides with the separation plate while flowing into the gas-liquid separation part and flowing, generating negative ions in the air and contacting the plate surface of the separation plate The water contained in the water adheres to the plate surface, is condensed into water droplets and is separated from the gas, and the gas containing negative ions is taken out of the machine.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. In FIG. 2, the device of the present invention comprises a vertical casing 1
The inside is divided into a water splitting section 2 and a gas-liquid separation section 3 by a partition wall 10,
The water splitting section 2 and the gas-liquid separating section 3 are communicated with each other at an inversion section 4 in the casing 1. At the upper part of the casing, a gas inlet 5 communicating with the water splitting unit 1 and a gas-liquid separating unit 3 are provided.
A gas outlet 6 communicating with the above is opened, and a water tank 7 is installed at the bottom of the casing 1. A blower 8 is connected to the gas inlet 5 as shown in FIG. 1, and the outside air is sucked by the operation of the blower 8 to press it into the water splitting section 2.

The water splitting portion 2 is a portion for jetting water into the gas that has been press-fitted and splitting it into fine water droplets. A nozzle 9 is built in the water splitting unit 2 as a water injection device, and a partition 11 tilted downward toward a partition wall 10 that partitions the inside of the casing 1 is installed immediately below the nozzle 9 to form a lower edge of the partition wall 10. Is bent at a right angle toward the lower side of the partition to form the weir 12.

The nozzle 9 jets water toward the partition wall 10 and the partition 11. The jetted water is the partition wall 10.
And, it collides with the partition 11 and splits to generate negative ions in the air due to the Leonard effect. In the water splitting section 2, the partition wall 10 also functions as a partition in terms of function.

The gas-liquid separating section 3 is a section that receives a gas containing fine water droplets generated in the water splitting section 2, removes water from the gas, and sends out a gas containing negative ions to the gas outlet 6. In the gas-liquid separation section 3, a separation plate 13 is projected from the inner wall of the casing 1 and the plate surface of the partition wall 10.

As shown in FIG. 3, each of the separation plates 13 crosses the gas flow path and projects in an inclined shape with respect to the gas flow direction to form a gas flow path in a zigzag shape, and is contained in the gas. The water is trapped on the plate surface. The separation plate 13 is inclined with respect to the gas flow direction at an obtuse angle θ ₁ from the inner surface of the partition wall 10 and the casing, or at an obtuse angle θ ₂ with respect to the gas flow direction. You may mix the overhang. The gas flows smoothly with respect to the obtuse-angled separating plate 13a.

On the other hand, the acute-angled separating plate 13b forms a so-called "pocket" for the flow of gas. Furthermore, the "drum" shaped separation plate 13c in which the obtuse angle separation plate and the acute angle separation plate are connected at their ends forms a smooth flow surface with respect to the flow of gas. In the embodiment, an obtuse angle separation plate 13a, a rectangular separation plate 13c, and an acute angle separation plate 13b are alternately arranged in this order from the upstream side of the gas to form a zigzag-shaped flow path. In the gas-liquid separating section 3, the inner wall and the partition wall of the casing also serve as a separating plate.

The reversing section 4 is a space inside the casing 1 formed below the water splitting section 2 and the gas-liquid separating section 3. The gas flowing out from the water splitting section 2 is turned back inside the reversing section 4 and introduced into the gas-liquid separation section 3. A drain pan 14 is provided on the inner bottom portion of the reversing section 4, and a drain port 15 opened in a part of the drain pan 14 communicates with the water tank 7 below the drain pan 14. The water tank 7 communicates with the nozzle 9 through a pipe 16 as shown in FIG. 1, and the water in the water tank 7 is pumped by a pump 17
It is drawn up by the nozzle 9 and ejected from the nozzle 9.

In the embodiment, the pump 17 is activated to pump up the water in the water tank 7 and eject it from the nozzle 9 into the water splitting section 2, and at the same time, activate the blower 8 to discharge the outside air into the gas inlet 5
Press into the water splitting part 2 from.

The water ejected from the nozzle 9 collides with the partition 11 and the partition wall 10 and is divided into fine water droplets to generate negative ions in the air. The negative ions aerodynamically act on the gas descending in the water division section 2. The water contained in the gas that is transported, pressure-fed into the reversing unit 4, reverses and rises in the reversing unit 4, and rises in the gas-liquid separation unit 3 is trapped on the plate surface of the separation plate 13. Is
Negative ions from which water has been removed are pneumatically transported, and humid air containing negative ions is sent from the gas outlet 6 to the outside air.

Most of the water sprayed on the screen 11 is
The water flows from the partition 11 through the partition wall 10 or the casing 1 and becomes drain water, which falls on the drain pan 14 and the water tank 7
It is returned to the inside and pumped up by the pump 17 to repeat the circulation.

In the present invention, the water jetted from the nozzle 9 collides with the partition wall 10 and the partition 11 and is split, the water splitting portion 2 is filled with the split water droplets, and most of the water drops along the partition wall 10. . The outside air is blown down from the gas inlet 5 opened at the upper part of the water splitting section 2, and the water from the nozzle 9 is jetted into the flow of gas, receiving the kinetic energy of the gas and forming water droplets. Is promoted, and a large amount of negative ions are generated in the air based on the Leonard effect and Simpson theory.

When the gas flows out from the water splitting section 2, the flow velocity is increased by being squeezed by the weir 12 of the partition wall 10 to flow out into the reversing section 4, and then violently collide with the drain pan 14 to be in the gas. Some of the contained water droplets are captured by the water film of drain water formed on the drain pan 14.

In the gas-liquid separating section 3, the moisture in the gas is removed every time the gas repeatedly collides with the separating plate 13 and the partition wall 10 or the inner wall of the casing 1. Of course, if only water in the gas is to be removed, separation plates may be extended to various places of the gas-liquid separating section 3 to form a labyrinth in the gas flow path, but the gas flow path becomes complicated. This is not preferable because the pressure loss increases. As shown in FIG. 2, substantially two bent paths and one pocket are formed in the gas-liquid separating section 3, so that the water contained in the rising gas can be sufficiently removed.
The water droplets captured by the separation plate 13 travel along the inner wall of the casing 1 or the partition wall 10 and fall on the drain pan 14, and are returned to the water tank.

Examples of the present invention will be shown below. The amount of ions generated in the air was measured using the device having the following specifications.

(Example 1) 1. Casing dimensions Depth (L) 275 mm x Width (W) 780 mm x Height (H) 708 mm (1) Water splitting part dimensions 310 (L) mm x 100 (W) mm x 350
(H) mm Inlet air channel size 100 mm × 100 mm Outlet air channel size 60 mm × 310 mm (2) Gas-liquid separation part dimension 310 (L) mm × 70 (W) mm × 350
(H) mm Inlet air channel size 70 mm × 310 mm Outlet air channel size 130 mm × 310 mm (3) Water tank dimension 180 (L) mm × 140 (W) mm × 50
(H) mm (4) Nozzle diameter 0.8φm Number 6 Nozzles were dispersed and installed within the range of 22φmm × 300mm in the nozzle pipe. (5) Partition size: 50.5 (W) mm × 310 (L) mm The partition has an inclination angle (θ ₁ ) of 129 ° with respect to the direction of the partition wall.
And is installed 69 mm below the nozzle position. (6) Weir Dimensions: 45 (W) mm × 310 (L) mm The weir is installed at right angles to the partition wall. (7) Separation Plate Two places as a flat plate separation plate and one place as a rectangular separation plate are installed in the gas-liquid separation part. ◎ Plate separation plate (2 places) Dimension: 43 (W) mm × 310 (L) mm Tilt angle θ ₂ : 120 °, θ ₃ : 60 ° ◎ V-shaped separation plate (1 place) Dimension: 43 (W) mm × 310 (L) mm Dimension: 72 (W) mm × 310 (L) mm Inclination angle θ ₄ : 28 ° Angle formed by the die: 90 ° A die separation plate formed by the above combination. (8) Blower 5m ³ / min Static pressure 30mmAg 1φ × 100V × 60Hz × 28W (9) Pump flow rate 12.5 l / min Static pressure 3mmAg Electric power 1φ × 100V × 60Hz × 30W

(Example 2) 1. Casing dimensions Depth (L) 227 mm x Width (W) 500 mm x Height (H) 595 mm (1) Water splitting dimensions 170 (L) mm x 95 (W) mm x 380
(H) mm Inlet air flow channel size 55 mm x 50 mm Outlet air flow channel size 95 mm x 170 mm (2) Gas-liquid separation part size 170 (L) mm x 65 (W) mm x 380
(H) mm Inlet air channel size 65 mm x 170 mm Outlet air channel size 65 mm x 180 mm (3) Water tank dimension 170 (L) mm x 120 (W) mm x 50
(H) mm (4) Nozzle diameter 0.8φm Number 3 Nozzles were installed dispersedly within a range of 22φmm × 170mm in the nozzle pipe. (5) Partition size: 50 (W) mm × 170 (L) mm The partition has an inclination angle (θ ₁ ) of 105 ° with respect to the direction of the partition wall.
And is installed 83 mm below the nozzle position. (6) Weir Dimensions: 50 (W) mm x 170 (L) mm The weir is installed at right angles to the partition wall. (7) Separation Plate Two flat plate separation plates and one rectangular separation plate are installed in the gas-liquid separation section. ◎ Lower installation flat plate separation plate Dimension: 43 (W) mm × 170 (L) mm Inclination angle (θ ₂ ): 135 ° ◎ Upper installation flat plate separation plate Dimension: 36 (W) mm × 170 (L) mm Inclination angle ( θ ₃ ): 55 ° ◎ V-shaped separation plate Dimensions: 33 (W) mm × 170 (L) mm Dimensions: 55 (W) mm × 170 (L) mm Inclination angle θ ₄ : 33 ° Angle formed by the V-shaped mold : Right angle A rectangular separation plate made by the above combination. (8) Blower Air volume 2m ³ / min Static pressure 30mmAg 1φ × 100V × 60Hz × 20W (9) Pump flow rate 12.5 l / min Postage 18m Electric power 1φ × 100V × 60Hz × 30W

The experimental results are shown in Table 1. The measured value is
The value measured at a position 10 cm away from the air supply port is shown.

[0033]

[Table 1]

As is apparent from the above examples, the obtained air is basically humid, and 80,000 negative ions can be generated in the air by using a water injection pump having a relatively small capacity. it can. This is 1,000 times the amount of negative ions contained in normal air.

[0035]

As described above, according to the present invention, the negative ions generated by the water splitting are pneumatically transported, and most of the fine water droplets generated by the water splitting are trapped during the flow of the gas. By separating and removing it from the inside, humid air containing a large amount of negative ions can be taken out of the machine. In particular, according to the present invention, the gas is supplied downward from above into the water splitting portion, and water is injected into the gas without countering the flow of the gas,
The water droplets can be effectively removed while the water containing the water droplets formed by jetting is flowed back in the casing, and air containing a large amount of negative ions can be obtained.

Further, according to the present invention, the inside of the casing is
The water-splitting part and the gas-liquid separation part can be formed simply by partitioning the partition wall, and the surface of the partition wall on the water-splitting part side is used for partitioning the jetted water into water droplets, and also the partition wall on the gas-liquid separation part side. It can be used as a separation plate that captures water in a gas on its surface.

Furthermore, the lower edge of the partition wall bent toward the water splitting portion serves as a weir, increasing the flow velocity of the gas flowing out of the water splitting portion, causing it to collide violently with the lower drain pan to remove the moisture contained in the gas. It can be captured by the drain pan to enhance the gas-liquid separation function.

In the present invention, the gas is folded back in the casing, and the gas-liquid separation is performed by contacting the plate surface of the separation plate arranged in the gas-liquid separation section. Therefore, a cyclone separator is used for the gas-liquid separation. It is suitable for use in an indoor installation type negative ion generator that does not require a high-power blower as in the case of use, can realize downsizing with low noise, and doubles as an air conditioner.

[Brief description of drawings]

FIG. 1 is a partially sectional front view showing an embodiment of the present invention.

FIG. 2 is a sectional side view.

FIG. 3 is a diagram showing a structure of a gas-liquid separation unit.

[Explanation of symbols]

 1 Casing 2 Water Splitting Section 3 Gas-Liquid Separation Section 4 Inversion Section 5 Gas Inlet 6 Gas Outlet 7 Water Tank 8 Blower 9 Nozzle 10 Partition 11 Partition 12 Weir 13 Separation Plate 14 Drain Pan 15 Drainage 16 Piping 17 Pump

Claims (5)

[Claims] 1. A negative ion generator having a water splitting section and a gas-liquid separating section, wherein the water splitting section and the gas-liquid separating section are formed along a flow path of a gas that is pressed in from the outside. The water splitting part is formed in the front stage of the flow path of the gas fed from the outside, and has a nozzle and a partition. The nozzle ejects water into the water splitting part, and the partition is , The water jetted from the nozzle is collided to break up into fine water droplets. The gas-liquid separation part is formed in the latter stage of the gas flow passage and has a separation plate, and the separation plate is a gas flow path. Negative ion generation characterized in that it is arranged so as to project inside, forms a gas collision surface, and traps the water contained in the gas on the plate surface to remove the water in the gas to be sent to the outside. apparatus. 2. The water splitting section forms a gas flow path that allows gas to flow from above to below, and the gas-liquid separation section forms a gas flow path that allows gas to flow from below to above, And an inversion part is formed between the gas separation part and the gas-liquid separation part. The inversion part is a part for inverting the flow direction of the gas sent from the water splitting part and introducing it into the gas-liquid separation part. The negative ion generator according to claim 1. 3. The water splitting section and the gas-liquid separation section are formed in parallel by partitioning the inside of the casing, and the lower space in the casing that connects the water splitting section and the gas-liquid separation section is inverted. The negative ion generator according to claim 2, wherein the negative ion generator forms a part. 4. The water splitting section and the gas-liquid separation section are partitioned by a partition in the casing, and the surface of the partition on the side of the water splitting serves as a screen for colliding the water ejected from the nozzle, and the gas-liquid separation section side. The negative ion generator according to claim 3, wherein the surface of the partition wall serves as a separation plate that traps water contained in the gas. 5. The lower end of the partition wall overhangs toward the water splitting portion to form a weir, and the weir reduces the outflow cross-sectional area of the gas flowing out of the water splitting portion to increase the flow velocity of the outflowing gas. The negative ion generator according to claim 4, characterized in that