JPH10216213A - Negative ion generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the increase of various germs in a water tank by irradiating water to be supplied to a water dividing part by means of ultra-violet rays through the use of a sterilizing light to remove the various germs and, after that, executing division into minute water drops. SOLUTION: A sterilizing light unit 19 is fitted to a part of a water supply pipe path 11 from the water tank 4 to a nozzle 9. The sterilizing light unit 19 is constituted by inserting a vertically long underwater sterilizing light 23 to a pipe 22 provided with a water feed port 20 and a water supply port 21 and flowing-in water is irradiated by the ultraviolet rays so as to remove the various germs in water. Sterilized water is supplied from the water supply port 21 to the nozzle 9 with a nozzle duct 11a and jetted as the minute water drops. Thus, negative ions are generated in the air and collected into the water tank 4. In this way, water is circulated while being sterilized between the water tank 4 and the nozzle 9 so as to prevent the increase of underwater various germs.

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 (waterfall effect).

[0002]

2. Description of the Related Art When a water droplet splits in the air, more precisely, when the water droplet collides with a metal plate serving as a collision wall and splits, negative ions are generated in the air nearby, and the water droplets become negative ions. The phenomenon of obtaining the same amount of positive charge as the Leonard effect (Lenard effect)
d's effect).
This phenomenon is called the waterfall effect because negative electricity exists in the air near the waterfall.

A method of generating negative ions by utilizing the Leonard effect is described in, for example, Japanese Patent Publication No. 5-587555. In this method, fine water droplets are generated from water by a fine water droplet manufacturing machine, and the fine water
Air is blown at ５０50 m / sec to form fine water droplet mixed air, and then the fine water droplet mixed air is passed through a separator to separate fine water droplets having a particle size of at least 1 μm to form ultrafine water droplet mixed air. Super fine water drop mixed air 1m
^{In step 3} , negative ions are generated in an amount of 1.25 × 10 ⁹ or more. In this prior example, the fine water drop making machine is a water splitting section, and the separator is a gas-liquid separating section. In the water splitting unit, a device that jets water at high pressure and collides with the impingement wall, a device that jets water onto a rotating disk, applies centrifugal force to the jet water to split it into fine water droplets, and ultrasonic humidification A device that vibrates water to break it into fine water droplets or a device that sprays water onto a rotating impeller and hits the water with the impeller to break it into fine water droplets is used. A separator is used.

In the above-described apparatus, fine water droplets generated in a water splitting section are blown, and the fine water droplets are separated from air in a cyclone separator, which is a gas-liquid separating section, to remove air containing negative ions to the outside. Can be taken out.

[0005]

Incidentally, the negative ion generator is provided with a water tank, pumps water in the water tank by a pump and supplies it to the water splitting section, and also supplies water to the water splitting section. Most of the water separated in the gas-liquid separation section
A method of recovering and recycling in a water tank is used.

[0006] In the water splitting section, water is split into fine water droplets in the air taken in from the outside air, and the dust collected in the water is taken into the water collected in the water tank, so that the water is contaminated. It is necessary to change the water in the tank later. Of course, not only dust in the air but also bacteria, viruses, molds and other germs floating in the air must be taken into consideration. When bacteria are taken into the water and the temperature conditions of the water are adapted to the survival of the bacteria, there is a risk of rapid propagation in the aquarium.

An object of the present invention is to provide a negative ion generator which removes various bacteria in water supplied to a water splitting section and prevents the propagation of various bacteria in a water tank.

[0008]

In order to achieve the above-mentioned object, a negative ion generator according to the present invention is a negative ion generator having a germicidal lamp in a supply line of water for supplying water to a water splitting section, The water splitting section is a section that splits the supplied water into fine water droplets and generates negative ions in the air.The germicidal lamp irradiates the water supplied to the water splitting section with ultraviolet light to remove various bacteria in the water. Is what you do.

The water tank contains water to be supplied to the water splitting section and collects most of the water supplied to the water splitting section. The water in the water tank is supplied by a pump. The germicidal lamp is installed in a water supply line connecting the water splitting unit and the water tank.

The germicidal lamp unit further includes a germicidal lamp unit having an underwater germicidal lamp inserted into a pipe. The germicidal lamp unit is connected to a water supply pipe. Is to irradiate ultraviolet rays while flowing through the gap between the germicidal lamp and the pipe to remove various bacteria.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings.

In FIGS. 1 to 3, the negative ion generator comprises:
The case 1 includes a water splitting section 2, a gas-liquid separation section 3, and a water tank 4.

The water splitting unit 2 splits water supplied from the water tank 4 into fine water droplets, and blows air containing the fine water droplets to the gas-liquid separating unit 3. Part 2
The water tank 4 is a part that separates and removes water droplets in the received air and sends out humid air containing negative ions to the outside.
The water to be supplied to the water splitting section 2 has been charged. 5 in the figure
Is an air intake opening at the bottom of the case 1;
Is an air supply port opened on the upper surface of the case 1. An air flow passage 7 is provided between the air inlet 5 and the air inlet 6, and the air flow passage 7 has a blower 8. The water splitting unit 2 and the gas-liquid separation unit 3 are located downstream of the blower 8. These are formed in the air flow passage 7 respectively.

The water splitting section 2 has a nozzle 9 and a wall 10, and a water supply line 11 leading to the nozzle 9 is provided with a pump 12.
Are connected to the inside of the water tank 4. A plurality of nozzles 9 are attached in parallel to a portion of a pipe 11a arranged in a horizontal posture, with the ejection port facing downward, and an impingement wall 10 is arranged below the nozzle 9 facing the ejection port of the nozzle 9. Has been established.

In the present embodiment, a block having an isosceles triangular cross section is used as the collision wall 10, and two inclined surfaces forming a right angle are used as the collision surface 13. In addition, a number of vertical grooves 14 are provided on the collision surface 13 in parallel.

The two slopes of the isosceles triangular block are used for the collision surface 13 solely based on experiments for measuring the amount of negative ions generated, and are not necessarily limited to this example. According to the experiment, the amount of negative ions generated is larger when the jet water from the nozzle 9 collides with the inclined surface than when the jet water collides with the surface perpendicular to the jet direction. Preferably. Further, even when the jetted water collides with the orthogonal surface, if a plurality of appropriate holes are made in the flat plate surface, the same or more negative ions are generated. According to the experiment, a large amount of negative ions are generated when the jet water collides with the convex portion and breaks into fine water droplets. It is desirable that no water film be formed on the collision surface of the jet water. The concave portion receives the jet water and forms a water film. Even if the jet water collides with the water film, the amount of negative ions generated is small. The humid air containing negative ions descends in the air flow passage 7 of the water splitting section 2,
Next, the air flow path 7 is turned back to ascend and introduced into the gas-liquid separation unit 3. In the air flow passage 7 of the gas-liquid separation unit 3,
Two or more baffles 15 are arranged in zigzag along the air flow passage 7. The air received in the gas-liquid separation unit 3 is
Baffle plate 1 while ascending in air flow passage 7 of gas-liquid separation unit 3
5, the baffle plate 15 captures fine water droplets contained in the air and removes them from the air.

Therefore, fine water droplets in the air are removed while the air passes through the gas-liquid separation section 3, and humid air containing negative ions is taken out from the air supply port 6 to the outside. Most of the water injected into the water splitting unit 2 and the water separated from the air in the gas-liquid separating unit 3 fall into the water tank 4 in the case 1 and are circulated.

In the present invention, bacteria and bacteria including viruses in water to be supplied to the water splitting section 2 are removed. A germicidal lamp is used to remove various bacteria. The germicidal lamp is a discharge lamp using a glass tube that transmits ultraviolet light well, and strongly emits 2537 nm ultraviolet light having a strong bactericidal power generated from mercury. In FIG. 3, a germicidal lamp unit 19 is attached to a part of the water supply pipe 11 connecting the water tank 4 and the nozzle.
The germicidal lamp unit 19 has a vertically long underwater germicidal lamp 23 inserted into a pipe 22 having a water supply port 20 and a water supply port 21. The germicidal lamp 23 is turned on. Ultraviolet rays are irradiated while flowing in the gap between the pipe 23 and the pipe 22 to remove various germs in the water, and sterilized water is supplied from the water supply port 21 to the nozzle pipe 11 a and jetted from the nozzle 9. The water injected from the nozzle 9 splits into fine water droplets to generate negative ions in the air, but most of the water is collected in the water tank 4 and the water is irradiated with ultraviolet light while repeating the circulation between the water tank 4 and the nozzle 9. As a result, propagation of various bacteria taken into the water is suppressed.

In the embodiment, a see-through window 16 is provided in a part of the case 1 so that the water splitting unit 2 can be seen through the see-through window 16 from the outside. Front panel 17 corresponding to the installation position
Is provided with a see-through window 16. The see-through window 16 is one in which a transparent plate such as a transparent glass or a transparent plastic is fitted into the opening of the panel 17. In order to express the image of the waterfall, it is preferable to form the see-through window 16 vertically long so that the hit wall 10 and a part of the space below the hit wall 10 can be seen through.

A lighting device 18 is provided in the case 1 to illuminate a state in which water jetted from the nozzle 9 collides with the impingement wall 10 and breaks into fine water droplets. Lighting equipment 1
LED, fluorescent lamp, incandescent lamp, EL, plasma light emission, etc. can be used for 8. As an illumination method, in addition to direct illumination by the illumination device 18, indirect illumination using an optical fiber or a prism can be used. it can. Since the water splitting portion 2 in the case 1 is a humid environment in which the water jetted from the nozzle 9 is scattered, the lighting device 18 needs to be waterproofed in the case of direct lighting. When performing indirect illumination using an optical fiber, the illuminating device 18 can be placed outside the air flow path 7 to expose the light emitting end of the optical fiber into the flow path in a humid environment. A germicidal lamp can be used as the lighting device.

[0021]

As described above, according to the present invention, in order to remove germs by installing a germicidal lamp in the water supply line to the water splitting section, it is necessary to keep fine water droplets generated in the water splitting section aseptic. Even if water spouted from the water splitting nozzle comes in contact with air and takes in bacteria in the air, it is collected in the water tank and sterilized by the next time it is spouted from the nozzle. Since the circulation is repeated between the water tanks, there is an effect that it is possible to generate clean negative ions without germs propagating in the water tank, and thus without releasing germs.

[Brief description of the drawings]

FIG. 1 is a perspective view of the device of the present invention.

FIG. 2 is a perspective view of the device of the present invention.

FIG. 3 is a view showing a water supply pipe to which a germicidal lamp is connected.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Case 2 Water splitting part 3 Gas-liquid separation part 4 Water tank 5 Air intake 6 Air supply port 7 Air flow path 8 Blower 9 Nozzle 10 Impact wall 11 Water supply pipeline 11a Nozzle pipe 12 Pump 13 Collision surface 14 Vertical groove 15 Baffle plate 16 Transparent window 17 Front panel 18 Lighting device 19 Sterilization lamp unit 20 Water supply port 21 Water supply port 22 Pipe 23 Sterilization lamp

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[Procedure amendment]

[Submission date] March 12, 1997

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction contents]

In the present invention, bacteria and bacteria including viruses in water to be supplied to the water splitting section 2 are removed. A germicidal lamp is used to remove various bacteria. Bacteria lamp is a discharge lamp using a glass tube to improve transmits ultraviolet light, emit strongly ultraviolet strong 2537 Å germicidal exiting from mercury. In FIG. 3, a germicidal lamp unit 19 is attached to a part of the water supply pipe 11 connecting the water tank 4 and the nozzle.
The germicidal lamp unit 19 has a vertically long underwater germicidal lamp 23 inserted into a pipe 22 having a water supply port 20 and a water supply port 21. The germicidal lamp 23 is turned on. Ultraviolet rays are irradiated while flowing in the gap between the pipe 23 and the pipe 22 to remove various germs in the water, and sterilized water is supplied from the water supply port 21 to the nozzle pipe 11 a and jetted from the nozzle 9. The water injected from the nozzle 9 splits into fine water droplets to generate negative ions in the air, but most of the water is collected in the water tank 4 and the water is irradiated with ultraviolet light while repeating the circulation between the water tank 4 and the nozzle 9. As a result, propagation of various bacteria taken into the water is suppressed.

Claims (3)

[Claims] 1. A negative ion generator having a germicidal lamp in a supply line of water for supplying water to a water splitting unit, wherein the water splitting unit splits supplied water into fine water droplets to form negative ion in air. The germicidal lamp is a device for irradiating ultraviolet light into water to be supplied to a water splitting unit to remove various bacteria in the water. 2. A water tank, which contains water to be supplied to the water splitting unit and collects most of the water supplied to the water splitting unit, wherein the water in the water tank is: 2. The negative ion according to claim 1, wherein the germicidal lamp is pumped and supplied to the water splitting unit, and the germicidal lamp is provided in a water supply pipe connecting the water splitting unit and the water tank. Generator. 3. A germicidal lamp unit having a germicidal lamp unit, wherein the germicidal lamp unit has a submerged germicidal lamp inserted into a pipe, is connected to a water supply pipe, and the germicidal lamp flows into the pipe. The negative ion generator according to claim 1 or 2, wherein the water is irradiated with ultraviolet rays while flowing through the gap between the germicidal lamp and the pipe to remove various bacteria.