RU2696768C1 - Photocatalyst device - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to photocatalytic disinfection and cleaning of environment, for example, water or air, and can be used in medical and preventive, administrative, public, office and residential premises. Photocatalytic device comprises a hollow optical fiber having the possibility of passing current along the fiber and with the possibility of filling at least one cavity with a gas capable of ionizing under the effect of an electric field created by current passing along the fiber to the degree of ionisation, at which gas emits light, wherein at least part of fiber contains photocatalytic material.EFFECT: excluding scattering and reducing intensity of radiation transmitted to photocatalyst on entire length of optical fiber with simultaneous reduction of overall dimensions.9 cl

Description

The invention relates to the field of photocatalytic disinfection and purification of the environment, for example, water or air, and can find application in medical, administrative, public, office, residential premises.

In recent years, photocatalytic technologies for water and air purification have occupied a solid niche among different purification methods. When a photocatalytic material is irradiated with light having an energy exceeding the band gap thereof, as a result of photoexcitation, electrons appear in the conduction band and holes appear in the valence band. As a result, these electrons and holes diffuse to the surface of the photocatalytic material and come into contact with oxygen and moisture or water, leading to the fact that these electrons are absorbed and act as reducing agents with the formation of superoxide anions. On the other hand, holes oxidize moisture or water to form hydroxyl radicals. As a result, these products exhibit a sterilizing effect and the ability to decompose organic compounds.

The prior art photocatalytic device (see patent RU 2273914 C1, H01J 61/35, C02F 1/32, publ. 04/10/2006) for treating water with ultraviolet radiation, consisting of a UV radiation source enclosed in a transparent UV radiation protective cover, on the outer surface of which a layer of photocatalytic coating based on titanium dioxide is applied. Such a device increases the disinfection efficiency and improves the organoleptic properties of the medium being processed due to the formation of hydroxyl and oxygen active radicals during photocatalysis that destroy both microorganisms and organic and inorganic compounds.

A disadvantage of the known device is the low ratio of the useful area of the photocatalyst to the useful reaction volume of the reactor.

Known photocatalytic device for air purification (see patent US 6771866, F21V 8/00, G02B 6/02, publ. 06.02.2003), taken as a prototype. The device uses an optical fiber with a photocatalyst deposited on it as a radiating surface. In this case, the optical fibers are attached to a massive substrate transparent to ultraviolet radiation, which serves as a conductor of radiation from the radiation source to the fiber with a photocatalyst. Fibers of various shapes are used - U-shaped, with two ends attached to the radiating substrate, spiral, branched, and random. The inlet air stream with impurities passes sequentially through the holes in the transparent substrate, the filter flows around the photocatalytic fibers in contact with the photocatalyst, and an oxidation / reduction reaction of impurities occurs, and then the air stream leaves the device.

The disadvantage of the prototype is the dispersion and decrease in the intensity of ultraviolet radiation transmitted to the photocatalyst due to absorption as it passes through the optical fiber.

The technical problem to which the present invention is directed is to create a fiber optic photocatalytic device, the efficiency of which will not depend on its length.

The technical result achieved by solving the technical problem consists in eliminating the scattering and reducing the intensity of the radiation transmitted to the photocatalyst over the entire length of the optical fiber with a simultaneous decrease in overall dimensions. Also, the inventive photocatalytic device expands the arsenal of technical means designed for disinfection and cleaning of the environment.

The technical problem is solved, and the technical result is achieved due to the fact that the photocatalytic device contains a hollow optical fiber made with the possibility of passing current along the fiber and filling at least one cavity with gas capable of ionizing under the influence of an electric field created by the current passing along the fiber, to the degree of ionization at which the gas emits light, while at least a portion of the fiber contains photocatalytic material.

The technical problem is solved, and the technical result is also achieved in the following particular embodiments of the photocatalytic device.

Current can pass through a conductor made in the form of a wire.

The hollow optical fiber can be made with a capillary structure, and the current can pass through a conductor formed by filling the capillary with a molten metal.

The hollow optical fiber can be made with a capillary structure, and the current can pass through a conductor formed by the deposition of a conductive film inside the capillaries.

A hollow optical fiber can be made with a capillary structure, and the conductor can be formed in a capillary filled with gas capable of ionizing under the influence of an electric field created by the current passing through the conductor to the degree of ionization at which the gas emits light.

The hollow optical fiber can be made of conductive material with the possibility of the passage of current through the optical fiber itself.

The photocatalytic material may be deposited on at least a portion of the surface of the optical fiber.

Photocatalytic material can be added to the material of the optical fiber.

The cavity intended for filling with gas can be made open and with the possibility of gas flowing through it.

Due to the use of radiation of ionized gas located inside the hollow optical fiber and ionized throughout the volume by passing the supplied electric current along the fiber, the need for an external radiation source is eliminated and, as a result, the radiation intensity transmitted to the photocatalyst is scattered and reduced over the entire length of the optical fiber. Due to this, the photocatalytic device can be scaled to the required size, because the increase in the length of the device will not be followed by the need to increase the size and power of the radiation source.

Due to the fact that instead of radiation sources, the device uses an electric current that ionizes the gas through an electric field to the degree of ionization at which the gas emits light, the proposed invention allows to reduce its own overall dimensions.

For the convenience of placing the conductor and gas inside the hollow optical fiber, it can be made with a capillary structure, and at the same time contain capillaries inside which a conductor is placed, for example, formed by filling the capillary with a molten metal, or formed by depositing a conductive film inside the capillaries.

The operation of the claimed photocatalytic device can be illustrated by the following example. For clarity, as one of the possible embodiments of the photocatalytic device, you can choose a hollow optical fiber with a capillary structure, at least part of the cavities of which are filled with nitrogen. Also, a conductor is placed inside the capillaries of the hollow optical fiber. A photocatalytic material, for example, titanium dioxide, is deposited on the outer surface of the optical fiber. A current is supplied to the conductor, after which the nitrogen inside the cavities of the optical fiber is ionized to such an extent of ionization that it begins to emit light in the ultraviolet spectrum. In this case, the radiation has an energy exceeding the band gap of the photocatalytic material (titanium dioxide). Titanium dioxide is irradiated with ultraviolet radiation and, as a result of photoexcitation, electrons appear in the conduction band, and holes appear in the valence band. Further, electrons and holes diffuse to the surface of the photocatalytic material and come into contact with oxygen and water, leading to the fact that electrons are absorbed and act as reducing agents with the formation of superoxide anions, and holes oxidize water with the formation of hydroxyl radicals. As a result, the environment is disinfected and cleaned (air, water).

The disclosed photocatalytic device expands the arsenal of technical means for disinfecting and cleaning the environment.

Claims (9)

1. Photocatalytic device containing a hollow optical fiber, made with the possibility of passing current along the fiber and with the possibility of filling at least one cavity with gas capable of ionizing under the influence of an electric field created by the current passing along the fiber to the degree of ionization at which the gas emits light, while at least part of the fiber contains photocatalytic material. 2. The device according to claim 1, in which the current passes through a conductor made in the form of a wire. 3. The device according to claim 1, in which the hollow optical fiber is made with a capillary structure, and the current passes through a conductor formed by filling the capillary with a molten metal. 4. The device according to claim 1, in which the hollow optical fiber is made with a capillary structure, and the current passes through a conductor formed by the deposition of a conductive film inside the capillaries. 5. The device according to claim 1, in which the hollow optical fiber is made with a capillary structure, and the conductor is formed in a capillary filled with gas capable of ionizing under the influence of an electric field created by the current passing through the conductor to the degree of ionization at which the gas emits light . 6. The device according to claim 1, in which the hollow optical fiber is made of conductive material with the possibility of the passage of current through the optical fiber itself. 7. The device according to claim 1, in which the photocatalytic material is deposited on at least a portion of the surface of the optical fiber. 8. The device according to claim 1, in which the photocatalytic material is added to the material of the optical fiber. 9. The device according to claim 1, in which the cavity intended for filling with gas is made open and with the possibility of gas flowing through it.