JP2002263181A - Simple deodorizer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a simple deodorizer with which an unpleasant odor generated in a general household or the like is efficiently treated by a simple device. SOLUTION: An ultraviolet lamp A for generating ozone and an ultraviolet lamp B for decomposing the generated ozone and generating radicals are provided in a space part where a gas (odor) to be treated is distributed. In the flowing direction of the gas to be treated, the ultraviolet lamp A is provided on an upstream side and the ultraviolet lamp B is provided on a downstream side.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a simple deodorizing apparatus, and more particularly to a simple deodorizing apparatus for efficiently removing odor locally generated in a room or the like by using an ultraviolet lamp. This simple deodorizing device can be effectively used for removing care odors in diaper changing and the like.

[0002]

2. Description of the Related Art In recent years, the population is aging rapidly, and the number of people requiring nursing care is increasing rapidly. When an elderly person having such reduced living independence function is made a resident, there is a concern that the indoor air environment may be deteriorated due to the generation of excrement and odor from the body. In particular, the problem of odor associated with nursing care at home is serious, impairing the caregiver's comfort and health, and placing a heavy burden on the psyche. Improvements in livability and comfort in hospitals and welfare facilities for the elderly are being considered, but implementing large-scale measures for the facilities will require a large capital investment and will increase the economic burden on residents. Is done. As a countermeasure for indoor odors, air purifiers and air conditioners with a deodorizing function and indoor deodorizers have been commercialized, but these have a relatively low concentration through a deodorizer for the purpose of removing odors in the entire room Is gradually improved over time, and is not suitable for removing high-concentration odors temporarily generated in diaper changing and the like. Therefore, at present, the odor is reduced by opening the window and changing the diaper to ventilate or masking the odor generated by the fragrance or the like. High concentrations of locally generated odors quickly fill the entire room, causing discomfort to the person, the caregiver and the surrounding people, as well as increasing the isolation of patients by moving away from close people. It is with. In addition, there is a case where a person is moved into a nursing home to avoid nursing care at home due to odor. As a method of removing such an odor, for example, a method of removing an odor component at room temperature by utilizing the oxidizing power of ozone as a deodorizing method using a catalyst is disclosed in Japanese Patent Publication No. 7-4114.
No. 6 discloses this. However, the odor that can be removed by the ozone catalyst method is limited, and excellent removal performance can be obtained for sulfur odor components such as hydrogen sulfide and methyl mercaptan, but the effect for ammonia and lower fatty acid odor is not sufficient. I can't say.

On the other hand, ultraviolet rays of 200 nm or less and 230-
By using an ultraviolet lamp that generates both 270 nm ultraviolet rays, in addition to ozone catalyst deodorization, the removal of harmful substances in gas that improves the efficiency of treating hydrogen sulfide and ammonia by the action of radical oxygen and photocatalysis (particularly Japanese Unexamined Patent Publication No. 9-206558) has been proposed. However, radical oxygen generated by irradiating ozone with light of 230 to 270 nm has a strong oxidizing power, and oxidizes sulfur-based odor components such as hydrogen sulfide and methyl mercaptan in a gas phase, and the generated sulfurous acid gas causes a catalyst to be generated. There is a problem of causing poisoning deterioration. Further, since two kinds of ultraviolet rays are simultaneously irradiated by one ultraviolet lamp, residual ozone which is not converted into radicals is easily generated. Therefore, in order to prevent leakage of harmful residual ozone, an ozone treatment means is additionally provided. It is necessary to provide.

[0004]

SUMMARY OF THE INVENTION An object of the present invention is to provide a simple deodorizing apparatus capable of efficiently treating an unpleasant odor generated in a general household or the like with a simple apparatus.

[0005]

Means for Solving the Problems As a result of intensive studies, the present inventors have found that an ultraviolet lamp A for generating ozone and an ultraviolet lamp B for decomposing generated ozone to generate radicals are treated as gas to be treated (odorous). The above object can be achieved by providing the ultraviolet lamp A on the upstream side and the ultraviolet lamp B on the downstream side, preferably in the flow direction of the gas to be treated, in the space through which the gas flows. As a result, they found that an ozone generator could be used, and completed the present invention. That is, the present invention is a simple deodorizing apparatus comprising: an ultraviolet lamp A or an ozone generator for generating ozone; and an ultraviolet lamp B for decomposing generated ozone to generate radicals. .

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION In a simple deodorizing apparatus of the present invention, a gas to be treated is introduced into a space provided with ultraviolet lamps A and B, and the gas to be treated is irradiated by ultraviolet rays from the ultraviolet lamp A, whereby That is, the oxygen in the air is converted into ozone, and then the ultraviolet light from the ultraviolet lamp B is irradiated to convert the generated ozone into radicals. The odor component is oxidized and decomposed, in particular, by radicals to make it odorless.

As the ultraviolet lamp A, a low-pressure mercury lamp made of quartz glass, which emits light of 190 nm or less, which is known as an ozone lamp, is preferably used. 19
Light energy having a wavelength of 0 nm or less is greater than the binding energy of oxygen molecules and excites oxygen in the air to generate ozone. The reaction rate is slow only by the gas phase reaction between ozone and the odor component, and it is difficult to efficiently remove the odor. However, by irradiating the generated ozone with light having a wavelength of 230 to 270 nm, the ozone is excited and has a high oxidizing power. Radicals are generated and can react with various odor components in a gas phase. The oxidizing power of radicals generated by photoexcitation of ozone is extremely high, and it is possible to oxidize and remove ammonia and fatty acids, which were difficult to remove by conventional ozone oxidation. The above-mentioned low-pressure mercury lamp that generates light having a wavelength of 190 nm or less simultaneously generates light having a wavelength of 230 to 270 nm, and a certain degree of deodorizing effect can be obtained with the ultraviolet lamp A alone. However, with the ultraviolet lamp A alone, most of the ozone is leaked without reacting, so that a sufficient deodorizing effect cannot be obtained.
Harmful ozone will leak. Then, by further installing the ultraviolet lamp B, ozone generates radicals, deodorization reaction is promoted, and ozone can be used effectively, and the problem of safety is solved because ozone is decomposed. Therefore, in the simple deodorizing apparatus of the present invention, it is preferable that the ultraviolet lamp A is provided on the upstream side and the ultraviolet lamp B is provided on the downstream side in the flow direction of the gas to be treated. As the ultraviolet lamp B, 230 to 270 n
A germicidal lamp, a chemical lamp, or the like that generates light having a wavelength of m can be used. In recent years, the ultraviolet lamp B has been widely used for sterilization of water treatment and the like, and higher output and longer life have been promoted. In order to treat a high-concentration odor, ozone must be produced in a corresponding amount and further radicalized. Therefore, by increasing the output of the ultraviolet lamp B or increasing the number of used ultraviolet lamps B in accordance with the amount of ozone generated, it is possible to deodorize high-concentration odor without leaking ozone without using a catalyst or the like. One of the features of the present invention is that
The use of different types of ultraviolet lamps does not necessarily require additional means for preventing leakage of residual ozone. It has been confirmed that the oxidizing power of radicals generated by ultraviolet irradiation is stronger than that of active oxygen generated on the surface of the ozone catalyst, and that ammonia and lower fatty acids can be oxidatively decomposed. There is no need to worry about depletion of the activated carbon due to ozone or poisoning of the catalyst. Thus, by disposing a plurality of ultraviolet lamps B, decomposition of ozone and removal of odor components can be promoted. The deodorizing reaction of the present invention is characterized in that it proceeds by radicals generated by irradiating ozone with an ultraviolet lamp B, and instead of an ultraviolet lamp A for generating ozone, a surface discharge type or silent discharge type ozone generator is used. May be used. Compared with the ultraviolet lamp B, the ultraviolet lamp A has a limited use at present and is mainly of a small size. Therefore, when an ozone generation amount is required, an ozone generator other than the lamp type can be used.
As such an ozone generator, for example, a silent discharge system such as a rotary electrode type, a glass tube tube type, or a plate electrode type can be used.

When irradiating ozone with an ultraviolet lamp, it is preferable to adjust the water content of the gas to be treated, if necessary. The amount of water in the gas to be treated is 5 to 30 g / m
It is preferably in the range of ³ , more preferably 10
20 g / m ³ . It has been confirmed that the decomposition of odor components and ozone is remarkably promoted by the presence of moisture. Radicals generated by irradiating the ozone with the ultraviolet lamp B are O 2
It is thought that the H radical is involved. Water content is 5g
If it is less than / m ^3, the generation of radicals will be reduced and the deodorization reaction will be insufficient, and ozone will leak easily, so the number of ultraviolet lamps will need to be increased, and it will be necessary to add activated carbon, catalyst, etc. to the subsequent stage. Not preferred.
Therefore, when the amount of water in the gas to be processed is small, it is preferable to supply water using a humidifier or the like. As the humidification, a method of directly spraying water, a method of heating water to evaporate or bubbling can be used. Since the temperature inside the simple deodorizer becomes higher than room temperature due to the irradiation of the ultraviolet lamp, it is possible to humidify the gas to be treated simply by installing a tray or the like at the lower part of the deodorizer. Further, even if the amount of water is more than 30 g / m ³ , there is almost no effect of accelerating the reaction, and depending on the use environment, dew condensation occurs in the simple deodorizing device, which is not preferable because it may cause trouble of the device.

In order to effectively use the generated ozone, it is necessary to efficiently irradiate the gas to be treated with the ultraviolet lamp B. As a result, the deodorization reaction is promoted in the gas phase and ozone is decomposed, so that there is no need to install an ozone deodorizing catalyst or the like in the subsequent stage. In order to uniformly irradiate the processing gas with light, the ultraviolet lamp B is preferably installed at the center of the space inside the deodorizing device through which the gas to be processed flows. The ultraviolet lamp B can be installed parallel or perpendicular to the gas flow direction. In particular, when a plurality of ultraviolet lamps B are installed, it is preferable to install them in a direction perpendicular to the gas flow direction as shown in FIG. 1 in order to design a compact apparatus. In this case, when the distance between the side wall of the deodorizing device and the center of the lamp is L1, and the total length of the glass tube portion of the lamp is L2, the ratio of L1 / L2 is 0.5 to 2, preferably 0.7 to 1. It is better to design the device so that If this ratio is lower than 0.5,
Most of the light is not involved in radical generation, but is absorbed by the side wall and is wasted. If the ratio exceeds 2, light does not sufficiently reach the vicinity of the side wall of the space, so that ozone and odor pass without being decomposed. For example, when the amount of gas to be treated is large, the cross-sectional area of the deodorizing device increases, and L1 /
When L2 exceeds 2, the number of lamps is increased in the horizontal direction so that light is irradiated entirely. If necessary, a deodorizing body may be provided at a stage subsequent to the ultraviolet lamp B.
As such a deodorant, an ozone deodorizing catalyst containing an oxide of a transition metal such as Mn, Fe, Ni, or Cu, which promotes a reaction between ozone and an odor component, can be used. In addition, activated carbon or impregnated activated carbon for an acidic gas, a basic gas, or a neutral gas obtained by treating activated carbon with an oxidizing agent such as an alkali component, an acidic component, or iodine can also be used. Further, adsorbents such as activated carbon and zeolite and M
n, Cu, Fe, Ni, Co, Zn, Ag, Pt, P
A combination of at least one catalyst component selected from d, Rh, Ru and Au can also be used. The simple deodorizing device of the present invention can also process ammonia and lower fatty acids which have been difficult to cope with by the ozone catalysis method or the activated carbon adsorption method, etc. An excellent deodorizing effect can be obtained. It is anticipated that such nursing care odors will temporarily occur locally when changing diapers or using a simple toilet. Therefore, by making a structure that can connect a flexible suction hose to the odor introduction port of the simple deodorizing device,
The odor generated locally can be efficiently collected. For example, when changing diapers in a hospital bed, a method of installing a large deodorizer in the crotch of the user is not preferable because there is a problem in space and workability, and a small deodorizer is insufficient due to insufficient air volume and insufficient deodorization capacity. No deodorizing effect is obtained. In addition, when the deodorizing device is installed at a position away from the user, efficient odor removal becomes impossible. Therefore, the diaper changing operation can be easily performed by introducing the odor into the simple deodorizing device via the flexible suction hose. Further, by providing a structure in which the space in the toilet of the portable toilet can be connected to the flexible suction hose of the simple deodorizing device, the portable toilet can be used indoors without diffusing odor. The suction hose may have an umbrella-shaped tip or a structure in which a wire mesh or a nonwoven fabric is used to prevent foreign substances other than odors from being sucked.

FIGS. 1 and 2 are explanatory views each showing an embodiment of the simple deodorizing apparatus of the present invention, FIG. 3 is an explanatory view of a conventional deodorizing apparatus, and FIG. It is explanatory drawing which showed one aspect at the time of use.

The simple deodorizing apparatus shown in FIG. 1 has a fan 2 for introducing a gas to be treated into the space of the apparatus 1 and a 185 nm fan.
And an ultraviolet lamp B4 that generates 254 nm light.

The simple deodorizing device shown in FIG. 2 has a fan 2 for introducing a gas to be treated into the space of the device 1, an ozone generating device 5 for supplying generated ozone in front of the fan 2,
And an ultraviolet lamp B4 for generating light of 254 nm.

The conventional deodorizing apparatus shown in FIG. 3 has fans 2 and 185 n for introducing the gas to be treated into the space of the apparatus 1.
It comprises an ultraviolet lamp A3 for generating m light and a catalyst layer 6 for decomposing ozone.

In FIG. 4, a flexible hose 7 is attached to a gas inlet of the apparatus 1 to be treated, and the tip of the flexible hose 7 is inserted into a portable toilet 8.

[0015]

EXAMPLES Hereinafter, the present invention will be described more specifically with reference to examples. Example 1 A deodorizing test for a complex odor was performed using the deodorizing apparatus shown in FIG. An ultraviolet lamp A and a 6-w ozone generating lamp (GL6ZH manufactured by Sankyo Electric Co., Ltd.) are installed at the lower part of the space of the deodorizing apparatus main body, and an ultraviolet lamp B is an 8 W germicidal lamp (GL manufactured by Toshiba Lighting & Technology Corporation) above the ultraviolet lamp B. −
8, the total length of the glass tube section is 26.5 cm). The gas to be treated was introduced into the main body of the deodorizer at 300 L / min by a fan provided at the lower part of the deodorizer. The room temperature tested was 25 ° C and the water content was 18g
/ M ³ , and the odor components were adjusted so that the gas concentration at the inlet of the deodorizer became 0.2 ppm of methyl sulfide, 2 ppm of ammonia, and 0.1 ppm of acetic acid, and the deodorizing effect on each component was examined. Table 1 shows the gas concentration measurement results at the outlet of the apparatus. In addition, the cross section of the space of the deodorizing device was 40 cm square, and a lamp was installed in the center thereof. L1 / L2 is 0.
It was 8. Example 2 A deodorizing test for a complex odor was performed using the deodorizing apparatus shown in FIG. Ozone generated by a silent discharge type ozone generator (OZ-4, manufactured by Ozone Co., Ltd.) is introduced into the deodorizer inlet from the outside in front of the fan, and the ultraviolet lamp B is used.
8W germicidal lamp (GL- made by Toshiba Lighting & Technology Corporation)
8, total length of the glass tube section is 26.5 cm).
The ozone generation amount was adjusted so that the ozone concentration after mixing with a fan was 2 ppm. Table 1 shows the results of performing the deodorization test in the same manner as in Example 1. The section of the space in which the ultraviolet lamp of the deodorizing device was installed was 40 cm square, and L
1 / L2 was 0.8. Comparative Example 1 In Example 1, using a deodorizing apparatus in which only the ultraviolet lamp A was installed and the germicidal lamp as the ultraviolet lamp B was not installed,
A deodorization test was performed in the same manner as in Example 1. Table 1 shows the results. Comparative Example 2 A deodorizing test for a complex odor was performed using the deodorizing apparatus shown in FIG. That is, a deodorization test was performed in the same manner as in Comparative Example 1 except that 1.5 liters of a honeycomb-shaped ozone catalyst were filled after the ultraviolet lamp A. Table 1 shows the results
Shown in

[0016]

[Table 1]

Although the ultraviolet lamp A shown in Comparative Example 1 alone has a certain degree of deodorizing effect, compared with Examples 1 and 2, the effect is insufficient, and ozone leaks, so there is a problem in safety. . In Comparative Example 2, an apparatus in which an ozone catalyst was added to Comparative Example 1 was shown, but almost no improvement in ammonia and acetic acid removal performance was obtained. on the other hand,
As shown in Examples 1 and 2, the deodorizing device of the present invention can remove a complex odor with a simple device configuration. In addition, an adsorbent such as activated carbon is not required unlike a conventional deodorizing apparatus, and maintenance is easy.

[0018]

The simple deodorizer of the present invention can be constituted only by an ultraviolet lamp and a fan, and can remove various odor components with a compact and simple facility. In addition, it can treat ammonia and lower fatty acids, which have been difficult to cope with with the ozone catalyst method or activated carbon adsorption method, etc., and has excellent deodorization against stool odor, urine odor and body odor generated with nursing The effect can be obtained.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing one embodiment of a simple deodorizing device of the present invention.

FIG. 2 is an explanatory view showing another embodiment of the simple deodorizing device of the present invention.

FIG. 3 is an explanatory view of a conventional deodorizing device.

FIG. 4 is an explanatory view showing one embodiment when using the simple deodorizing device of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Deodorizing device main body 2 Fan 3 Ultraviolet lamp A 4 Ultraviolet lamp B 5 Ozone generator 6 Deodorant (ozone catalyst) 7 Flexible hose 8 Portable toilet

Claims (3)

[Claims] 1. A simple deodorizing device comprising an ultraviolet lamp A or ozone generator for generating ozone and an ultraviolet lamp B for decomposing generated ozone to generate radicals. 2. The simple deodorizing device according to claim 1, wherein the ultraviolet lamp A is an ultraviolet lamp that generates light having a wavelength of 190 nm or less. 3. The simple deodorizing apparatus according to claim 1, wherein the ultraviolet lamp B is an ultraviolet lamp that generates light having a wavelength of 230 to 270 nm.