SU1729480A1 - Bactericidal vacuum cleaner - Google Patents

Abstract

The invention relates to household cleaning equipment, namely, vacuum-irradiators intended for cleaning premises, cleaning clothes, carpets, upholstered furniture with a volume-spatial structure of upholstery fabric. The aim of the invention is to enhance the functionality by photobactericidal treatment of the cleaning zone. For this purpose, the vacuum cleaner is equipped with a light processing unit with a radiation source optically conjugated in a housing with a collector nozzle and connected to a power supply unit; a brush feed with optical fiber bristles optically connected to the radiation source is located on the medium of the collector nozzle. In addition, the light processing unit of the cleaning zone contains a gutter-shaped deflector of the light and air flows; 2 hp f-ly, 4 ill. WITH

Description

The invention relates to household appliances for cleaning clothes, carpets, upholstery fabrics of soft furniture and can be used in vacuum cleaners for cleaning apartments, concert halls and theaters, hotels, passenger cars, cabins of motor ships, aircraft salons, buses, cars.

Traditional household vacuum cleaners of the conventional device are known, comprising a housing, an air intake manifold nozzle and a power supply unit.

These household vacuum cleaners have an insufficiently compacted layout.

The vacuum cleaning process is based on removing dust from the treatment area and transporting suspended particles, including the transfer of microorganisms, to the dust collector. However, the microorganisms that remain in the depths of the carpet pile or the volume-porous structure of the tissues are in an intact state and after such cleaning can continue their development. This is a significant disadvantage of the known vacuum cleaners.

The purpose of the invention is to expand the functionality of the vacuum cleaner due to the photobactericidal effect and density of the layout.

FIG. 1 shows a bactericidal vacuum cleaner, general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 - install deflector

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light and air flow; in fig. 4 - deflector wall.

The bactericidal vacuum cleaner comprises a housing 1, a collection nozzle 2 of the air-suction channel 3, and a power supply unit 4. The vacuum cleaner is provided with a light processing unit 5 including a radiation source 6, preferably of the ultraviolet range. The radiation source is optically coupled to the collector nozzle 2 and is connected to the power supply unit 4 in the housing 1. The assembly 5 is mounted on the housing 1 on the plug connection and can be detached from it. And the radiation source 6 can be outside the aggregate 5. The light processing unit 5 has a brushing irradiator 7 with a light-emitting bristle 8 which is optically coupled to the radiation source b at the shear of the collector nozzle. Light bristles are made of synthetic fibers. The light processing unit 5 comprises a groove-shaped deflector 9 of light and air streams. The deflector is located in the air suction duct 3 between the collector nozzle 2 and the radiation source 6. It is made of an alloy based on aluminum, plastic or other lightweight materials. The concave surface 10 of the deflector is the limiter of the evacuated space, and the convex surface 11 forms the reflector 12 of the crescent-shaped focline 13. The ends of the light-guide bristles 8 of the brush irradiator 7 are inserted into the area of the focline narrowing.

During the operation of the bactericidal vacuum cleaner, an air flow 14 and an air vacuum in the collector nozzle 2 are created in the air suction channel 3, and the luminous flux 15 of the radiation source 6 enters the crossing direction through the collector nozzle 2 onto the surface 16 of the workpiece 17. In this case, in the processing zone 18 At the same time, two processes take place: the removal of airborne dust and the photobactericidal effect of ultraviolet radiation on microorganisms both in the airflow and on the surface of the object being treated. Ultraviolet radiation enters the treatment area from the irradiator 7 through the light-guided bristle 8, penetrating into the deep areas of the hairy-porous structures of the object being processed. The process of photobactericidal treatment of surface

objects are also realized when cleaning with the use of liquid and foaming detergents, since the light emitting ends of the bristles 8 self-clean when mechanically interacting with the subject 17. The deflector in the compacted arrangement of the unit 5 is the common dividing wall of the light flux 15 in focline 13 and the air flow 14 in the channel 3. The reflector 12 directs the light flux along the focline to the area of its constriction and through them to the bristles 8, which mechanically expels dust particles and irradiates the surface to be treated. s. At the same time, the deflector protects the light-transmitting cavity of foclin from dust, and its reflector 12 is reliably cooled through the wall by an air stream 14 from the side of the concave surface 10.

Practical use of a bactericidal vacuum cleaner provides increased purity of treatment associated with exposure to ultraviolet radiation on microorganisms, and achieving a compact design.

Claims (3)

1. A bactericidal vacuum cleaner comprising a housing, a collector nozzle of an air intake duct and a power supply unit, characterized in that, in order to enhance the functionality due to a photobactericidal effect and arrangement density, it is equipped with a light processing unit with a radiation source that is optically conjugated housing with a collector nozzle and connected to a power supply. 2. Vacuum cleaner pop. 1, characterized in that the light processing unit has a brush feed with a light-emitting bristle optically coupled to a radiation source at the cut-off of the collector nozzle. 3. Vacuum cleaner on PP. 1 and 2, characterized in that the light processing unit comprises a groove-shaped deflector of the light and air streams located in the air suction channel between the collector nozzle and the radiation source, the concave surface of which is the limiter of the evacuated space, and the convex surface forms a reflector of the sickle-shaped focline in the constrictions of which the ends of the light bristle are inserted. ,four.