JP2561901B2 - Active oxygen production equipment and active oxygen water production equipment - Google Patents

Description

TECHNICAL FIELD The present invention relates to an active oxygen and active oxygen water producing apparatus having a strong bactericidal action, oxidizing action and the like.

[Prior art and its problems]

Since active oxygen in the gas produced by decomposition of ozone and active oxygen water in which this active oxygen is dissolved in water have a strong bactericidal action and oxidative action, in recent years, for example, the freshness of foods is maintained and the storage period is extended. Therefore, it has come to be widely used for cleaning and bleaching foods, deodorizing in refrigerators, and also for decolorizing and sterilizing sewage water. By the way, conventionally, in order to decompose ozone and a part of ozone to produce active oxygen, a method using a silent discharge and a method using an ultraviolet ray have been used. Silent discharge is to generate ozone by glow discharge between electrodes in a space containing oxygen, and ozone generation efficiency is high, but it is necessary to dry and dehumidify air to be used in advance,
It is impossible to control the amount of ozone generated, and NO
There is a problem that x also occurs.

On the other hand, the mechanism of generation of ozone and active oxygen by ultraviolet rays is considered as follows.

O ₂ (air) + hν ₁ → O ^* ₂ → 20 (1) (hν ₁ = light with a wavelength of 200 nm or less) O + O ₂ (air) + M → O ₃ + M (2) (M = N ₂ , O ₂ ) O ₃ + Hν ₂ → O (active oxygen) + O ₂ (3) (hν ₂ = a wide range of light including a wavelength of 300 nm or less) In water, OH generated by the following formula exerts oxidizing power.

O (active oxygen) + H ₂ O → 2OH (4) Here, the low-pressure mercury lamp with mercury enclosed has a wavelength of 185n.
Low-pressure mercury lamps have been used as a UV source because they emit light at m and 254 nm. However, the ultraviolet light emitted from the low-pressure mercury lamp mainly emits light having a wavelength of 254 nm, and the light of 185 nm is a subordinate and linear spectrum. It is only about 2-3%, which is extremely low. That is, the ozone generation efficiency and the ozone decomposition efficiency that are indispensable for obtaining active oxygen are extremely low, and therefore the active oxygen generation efficiency is extremely low. 3 shows the relationship between the absorption coefficient when hν ₂ is absorbed by O ₃ and the wavelength of hν _{2 in} the formula (3), and the dotted curve shows the hν in the formula (1). Absorption coefficient and hν ₁ when ₁ is absorbed by O ₂
The relationship between the wavelengths is shown below.
The absorption efficiency of 185 nm and 254 nm light for oxygen and ozone is low. Therefore, in order to sufficiently absorb the light of 185 nm and 254 nm into oxygen and ozone in the air and effectively use it, it is necessary to make the air layer receiving the radiation from the low-pressure mercury lamp, for example, 20 cm or more in thickness. There is a problem that the device becomes large. Furthermore, the low-pressure mercury lamp has a strong dependence of the enclosed mercury vapor pressure on the ambient temperature, and emits light efficiently at temperatures near 10 to 60 ° C, but at temperatures below this,
The amount of light emitted at 185 nm and 254 nm becomes extremely small, and there is also a problem that it takes several tens of minutes from lighting to a steady state.

[Object of the Invention]

Therefore, the present invention provides an active oxygen production apparatus and an active oxygen water production apparatus that are compact, have high production efficiency of active oxygen and active oxygen water, have low environmental temperature dependence, and do not require dehumidification or generate NOx. The purpose is to do.

[Structure of Invention and Its Action]

The active oxygen production apparatus of the present invention has at least 150 nm to 1 nm.
Ultraviolet light emitted in oxygen or a gas containing oxygen, in which a rare gas containing xenon gas as a main component and a halogen gas are enclosed in a polycrystalline ceramic tube having a light transmission region in the wavelength range of 80 nm and 200 nm to 300 nm. It is characterized by comprising a lamp and a power supply device for exciting and emitting the ultraviolet lamp.

In addition, the active oxygen water production device has at least 150 nm to 1 nm.
Ultraviolet lamp in which rare gas mainly composed of xenon gas and halogen gas are enclosed in a polycrystalline ceramic tube having a light transmission region in the wavelength range of 80 nm and 200 nm to 300 nm and oxygen or a gas containing oxygen exists. It is characterized by comprising an active oxygen generating chamber arranged in the casing, a power supply device for exciting the ultraviolet lamp to emit light, and a means for dissolving active oxygen generated in the active oxygen generating chamber in water.

That is, according to the present invention, both claim 1 and claim 2
Since it generates active oxygen using ultraviolet rays, it does not require dehumidification or generate NOx as in silent discharge. And the lamp used as a UV source is at least 150n
Since a rare gas containing xenon gas as the main component and a halogen gas are enclosed in a polycrystalline ceramic tube having a light transmission region in the wavelength range of m to 180 nm and 200 nm to 300 nm, the light transmittance is It is extremely high, and its emission wavelength is 207 nm and 185-18, as shown in FIG.
It is a continuous spectrum with a peak of 8 nm light, and the total amount of light that contributes to the production of active oxygen by ozone and ozone decomposition is extremely large. Therefore, a large amount of light having a wavelength required for generating ozone and active oxygen can be emitted to oxygen or a gas containing oxygen with respect to input electric power, and the active oxygen generation efficiency becomes extremely high. Further, this ultraviolet lamp has a large amount of light having a wavelength of 207 nm or less, but as can be understood from FIG. 3, it has a large absorption coefficient for oxygen and ozone and is well absorbed by oxygen and ozone. When the present ultraviolet lamp is made to emit light in the casing containing the gas containing, the casing may be small and a compact structure can be obtained. And, unlike the low-pressure mercury lamp, this ultraviolet lamp has almost no environmental temperature dependency, has an advantage that it radiates ultraviolet rays efficiently even at a low environmental temperature of 10 ° C. or less, and has a fast start-up at the time of starting. .

〔Example〕

The present invention will be specifically described below based on the embodiments shown in the drawings.

FIG. 1 shows a sectional view of an ultraviolet lamp 1 used in the manufacturing apparatus of claims 1 and 2. Tube 11
At least 150 nm to 180 nm and 200 nm to 300 nm is made of a polycrystalline ceramic having a light transmission region in the wavelength region, but in the present embodiment, the inner diameter is 6 mm, from a polycrystalline alumina tube that transmits well in the vacuum ultraviolet region. Become. Caps 12 made of, for example, niobium are fitted and sealed at both ends of the tube 11. Electrodes 13 are attached to the cap 12, and the interval (discharge length) is 8 cm. Electrode 13 is stainless steel tube 1
It consists of 4 and a tungsten coil 15 placed inside it, and the coil 15 contains SrO, BaO and C as emitters.
AO ternary alkaline earth oxide is applied. The tube 11 is filled with xenon gas or a gas containing xenon gas mixed with several% of other rare gas and halogen gas. The pressure of the charged gas is preferably about 50 to 500 Torr. If the enclosed gas pressure is lower than 50 Torr, the total amount of light emission is reduced, moreover, the light emission in the wavelength range where the transmittance of the tube 11 is low is increased, and the amount of light emitted at a wavelength of 200 nm or less, which is a wavelength at which ozone can be generated for input power Ratio or the ratio of light having a wavelength of 200 to 300 nm, which is the wavelength range for decomposing ozone, that is, the active oxygen generation efficiency decreases. On the other hand, when the enclosed gas pressure is higher than 500 Torr, the discharge starting voltage and the discharge sustaining voltage become high, so that the power supply device becomes large, the cost becomes high, and the economical efficiency becomes poor.

When the ultraviolet lamp 1 is excited and emitted by electric power such as microwave, radio wave, commercial AC or DC, the second
A continuous spectrum as shown in the figure is obtained. Figure 2 shows
It is a spectrum when xenon gas is filled at 200 Torr and iodine gas as a halogen gas is filled at a pressure of 2 Torr, and it is a spectrum when it is made to emit light under the condition of high frequency power of about 50 KHz and high power of 3 W / cm. Light with a wavelength of 200 nm or less,
200 to 300, which is the wavelength range that efficiently decomposes ozone
A lot of nm light is emitted. That is, the formulas (1) and (3) progress well, and active oxygen can be efficiently generated. Unlike the low-pressure mercury lamp, the ultraviolet lamp 1 uses a gas containing xenon gas as a main component, so that it hardly depends on the ambient temperature and emits light efficiently even at a low temperature of 10 ° C. or less. The startability at the time is also excellent. Not only iodine gas but also other halogen gas such as chlorine and bromine can be used alone or in combination to obtain the same emission wavelength spectrum, so that ozone can be efficiently generated and active oxygen can be efficiently generated. can do.

Next, FIG. 4 shows the first embodiment of the active oxygen production apparatus according to claim 1.
An example will be described. The ultraviolet lamp 1 is arranged in a rectangular casing 3, and the power supply device 2 is attached to the casing 3.
Is excited by light emission. Here, as described above, the size of the casing 3 is much smaller than that using a conventional low-pressure mercury lamp because the ultraviolet lamp 1 emits light having a wavelength that is easily absorbed by air and ozone. . A filter 4 is attached to an opening on one end side of the casing 3, and an air intake blower 5 is arranged inside thereof. Then, when the blower 5 operates, oxygen in the atmosphere sucked through the filter 4 is radiated with light from the ultraviolet lamp 1 to generate ozone, and this ozone is decomposed to generate active oxygen. The active oxygen is an air forced inflow / outflow type device configured to discharge the active oxygen together with undecomposed ozone from the opening on the other end side of the casing 3 to guide the active oxygen toward the object to be treated. In this embodiment, the ozone concentration when the ultraviolet lamp 1 is made to emit light with an input power of 15 W and air is flown at a flow rate of 10 / min is about
It was 2.5 ppm. The tube of this UV lamp 1
When 11 was made to absorb light with a wavelength of 200 nm or more, the ozone concentration was about 2.9 ppm, so it is estimated that about 0.4 ppm of ozone was decomposed into active oxygen. That is, it was possible to obtain extremely high generation efficiency of active oxygen as compared with the conventional example using the low-pressure mercury lamp.

FIG. 5 is used, for example, for sterilizing bacteria floating in the air in the refrigerator and for deodorizing the air in the refrigerator. The ozone decomposing catalyst is provided at the active oxygen outlet of the device shown in FIG. 6 is attached so that ozone odor does not come out. That is, this device is arranged in a refrigerator, and when the air in the refrigerator is inhaled into the casing 3, it produces active oxygen and at the same time treats bacteria etc. in the air with this active oxygen and produces no odor without ozone. The air is discharged from the casing 3.

In FIG. 6, for example, a gutter-shaped mirror 7 treated with alumite is arranged so as to surround the ultraviolet lamp 1, and the power supply device 2 is attached to this mirror 7. Active oxygen is produced from oxygen. And
An object to be processed or air in which a minute object to be processed is placed below the ultraviolet lamp 1 is irradiated with active oxygen to perform an oxidation process or a sterilization process.

Next, FIG. 7 shows a first embodiment of the active oxygen water producing apparatus according to claim 2. In FIG. 7, the inside of the casing 3 is the active oxygen generation chamber 8, and the structure thereof is the same as that of the device shown in FIG. 4, but the active oxygen generated in the active oxygen generation chamber 8 is transferred to the water tank 20 through the pipe 21. Be guided. On the bottom of the aquarium 20,
As a means for dissolving active oxygen in water, a nozzle 22 in which a large number of minute ejection holes are formed is arranged, and the active oxygen guided by the pipe 21 is ejected from this nozzle 22 into water and dissolved. , Active oxygen water is produced. Also at this time, active oxygen is efficiently generated in the active oxygen generation chamber 8, so that active oxygen water can be efficiently produced with a small amount of input power.

FIG. 8 shows another embodiment of the apparatus according to claim 2, in which a sprayer 23, which is a means for dissolving active oxygen in water, is attached to the tip of the pipe 21, and inside the water tank 20. Water spouts in a mist with the air containing active oxygen sent from the pipe 21 to form active oxygen water droplets. The active oxygen water droplets are sprinkled on, for example, vegetables to be used for maintaining freshness. Also at this time, the active oxygen water droplets can be efficiently produced.

〔The invention's effect〕

As described above, the active oxygen production apparatus and the active oxygen water production apparatus of the present invention have at least an ultraviolet light source.
Since an ultraviolet lamp in which a rare gas containing xenon gas as a main component and a halogen gas are enclosed in a polycrystalline ceramic tube having a light transmission range in the wavelength range of 150 nm to 180 nm and 200 nm to 300 nm is used, ozone is generated. The wavelength that contributes to 200 nm or less and the wavelength that contributes to the decomposition of ozone is 200 ~
It emits a large amount of light of 300 nm, and there is a large amount of light with a wavelength that absorbs oxygen and ozone well. Therefore, even if the apparatus is downsized, these lights can be fully utilized, and active oxygen or active oxygen water can be efficiently produced with a small amount of input power. And, this ultraviolet lamp has almost no environmental temperature dependency, emits light efficiently even at low temperature, and has excellent startability at low temperature, but further, there is no need for dehumidification and NOx is not generated. .

[Brief description of drawings]

FIG. 1 is a sectional view of an ultraviolet lamp, FIG. 2 is an explanatory diagram of an emission spectrum, FIG. 3 is an explanatory diagram of an absorption coefficient, FIG. 4 is an explanatory diagram of a first embodiment of claim 1, FIG. 6 is an explanatory view of another embodiment, FIG. 7 is an explanatory view of a first embodiment of claim 2, and FIG. 8 is an explanatory view of another embodiment. 1 ... UV lamp, 11 ... Tube 13 ... Electrode, 2 ... Power supply device 3 ... Casing, 4 ... Filter 5 ... Blower, 6 ... Ozone decomposition catalyst 7 ... Mirror, 8 ... Active oxygen Generation chamber 20 ... water tank, 21 ... pipe 22 ... nozzle, 23 ... sprayer

Claims (2)

(57) [Claims] 1. At least 150 nm to 180 nm and 200 nm to 300
An ultraviolet lamp that emits light in oxygen or a gas containing oxygen, in which a rare gas containing xenon gas as a main component and a halogen gas are enclosed in a polycrystalline ceramic tube having a light transmission region in a wavelength range of nm, and A device for producing active oxygen, comprising a power supply device for exciting an ultraviolet lamp to emit light. 2. At least 150 nm to 180 nm and 200 nm to 300
An ultraviolet lamp in which a rare gas containing xenon gas as the main component and a halogen gas are enclosed in a polycrystalline ceramic tube that has a light transmission region in the wavelength range of nm is placed in the casing where oxygen or a gas containing oxygen exists. And a means for dissolving the active oxygen generated in the active oxygen generating chamber in water.