WO2022060238A1

WO2022060238A1 - Device for disinfecting air

Info

Publication number: WO2022060238A1
Application number: PCT/RU2020/000486
Authority: WO
Inventors: Михаил Юрьевич ВИНОКУРОВ; Андрей Олегович МАМЕДОВ
Original assignee: Михаил Юрьевич ВИНОКУРОВ; Андрей Олегович МАМЕДОВ
Priority date: 2020-09-17
Filing date: 2020-09-17
Publication date: 2022-03-24

Abstract

The invention relates to the field of public health, and more particularly to devices for disinfecting air, i.e. for reducing to a safe level the contamination of air with pathogenic microorganisms and viruses, and can be used in private settings as a personal respiratory protection means, as well as for protecting civilian and military medical staff. The claimed device for disinfecting air comprises a housing and a face portion, which are interconnected by an air pipe, and, disposed inside the housing, a source of ultraviolet radiation and partitions which, in the internal volume of the housing, form channels for circulating the air that is undergoing disinfection, wherein the housing has an inlet aperture for supplying air from the environment and an outlet aperture for discharging the disinfected exhaled air into the environment. The housing comprises an internal wall which divides the internal volume of the housing into a disinfecting chamber for the air to be inhaled, and into a disinfecting chamber for the exhaled air, wherein the partitions and the internal wall of the housing are made of a material that transmits ultraviolet radiation.

Description

AIR DISINFECTION DEVICE

The utility model relates to the field of healthcare, in particular to devices for air disinfection, i.e. to reduce the contamination of the air with pathogenic microorganisms and viruses to a safe level, and can be used privately as an individual means of respiratory protection, and to ensure the protection of civil and military medicine workers.

A device for air disinfection is known, described in US patent No. 55165395 and selected as the closest analogue, containing a housing and a front part that are connected by an air duct, as well as a source of ultraviolet radiation and partitions located inside the housing, forming channels for circulating disinfected air in the internal volume of the housing, while in the housing, in particular in the walls of the housing, there is an inlet for supplying air from the environment and an outlet for removing disinfected exhaled air into the environment; the partitions, as well as the walls of the housing, are made of a material that does not transmit ultraviolet radiation, and the disinfection of the air inhaled and exhaled by the user is carried out alternately in the same volume, limited by the walls of the housing.

The disadvantages of the described technical solution include its design. Thus, the implementation of partitions from a material that does not transmit ultraviolet radiation leads to a reduction in the processing time of the air flow in the channels for the circulation of disinfected air, which in turn leads to a decrease in the bactericidal effectiveness of the device as a whole. The use of the entire internal volume of the housing for the implementation of disinfection of both inhaled and exhaled air by the user leads to a decrease in the processing time of both inhaled and exhaled air, reducing the efficiency of the device.

SUBSTITUTE SHEET (RULE 26) The objective of the claimed utility model is to create a device for air disinfection, the design of which would ensure the achievement of a technical result, which consists in increasing the efficiency of the device. Additional technical results achieved in the implementation of the proposed device are the simplicity, durability and mobility of the device.

The problem is solved by the fact that a device for air disinfection has been developed, containing a body and a front part, which are connected by an air duct, as well as a source of ultraviolet radiation and partitions located inside the body, forming channels for the circulation of disinfected air in the internal volume of the body, while an inlet is made in the body for supplying air from the environment and an outlet for removing disinfected exhaled air into the environment, where the housing contains an inner wall separating the internal volume of the housing into an inhaled air disinfection chamber and an exhaled air disinfection chamber, while the partitions and the inner wall of the housing are made of a material, transmitting ultraviolet radiation. Preferably, the ultraviolet transmissive material is selected from the group consisting of quartz glass and uvio glass.

The described design of the claimed utility model makes it possible to ensure a high efficiency of the device, since due to the construction of the partitions and the inner wall of the housing from a material that transmits ultraviolet radiation, as well as due to the division of the internal volume of the housing into a chamber for disinfecting inhaled air and a chamber for disinfecting exhaled air, the period of time increases, during which the effect of ultraviolet radiation on the inhaled air, which enters the chamber from the environment, is carried out, which is due both to the permeability of the material used, and the length of the path that the air flow passes, circulating through the formed by means of established partitions to the channels, while simultaneously with the specified process, the process of disinfection of exhaled air is carried out. In general, the above causes a high bactericidal effectiveness of the device, safe operation of the device both for the user of the device and for the people around him, a sufficient rate of air disinfection, which prevents the user of the device from having difficulty breathing. In addition, the use of widely available and inexpensive materials determines the high economic efficiency of the implementation of the proposed device for both permanent and occasional use in severe epidemiological conditions. Also, the organization of channels for the circulation of disinfected air makes it possible to ensure the optimal overall dimensions of the device, which, in turn, ensures high mobility of the device.

It is expedient to implement the proposed utility model in which a fan is installed on the device case, which is configured to blow air into the chamber for disinfecting the inhaled air from the environment. Thus, due to forced air injection, the user's breathing through the device is facilitated, in addition, a positive pressure is created inside the device, which prevents air contaminated with infectious agents from entering the respiratory tract from outside the device. Also, the overpressure in the inhalation air decontamination chamber prevents the exhaled air from mixing with the inhaled air.

Preferably, the device is provided with a rechargeable UV source and fan.

Also preferably, the housing walls are made of a material that does not transmit ultraviolet radiation, which prevents undesirable effects of ultraviolet radiation on the environment of the user.

Preferably, the ultraviolet radiation source is installed in a chamber for decontamination of inhaled air next to the separating partition, however, it is obvious that the specified source of ultraviolet radiation can be installed differently, while providing radiation exposure to the internal volume of both chambers formed in the housing. Most preferably, the ultraviolet radiation source is an ultraviolet lamp.

It is expedient to implement a utility model in which the front part of the device is a mask, half mask or quarter mask, however, it is obvious that any other device can be used, the technical implementation of which ensures that this device performs similar functions.

It should be noted that the developed device for air disinfection does not require special maintenance, since all components are easily replaceable and are available on the market even for self-replacement of failed elements by the user (for example, an ultraviolet lamp). Such simplicity also determines the durability of the device, since the structural elements of the device have a long service life, and their replacement does not affect the quality of the device.

The claimed utility model is illustrated with the help of the following graphic materials: Fig. 1 is a general view of one of the preferred embodiments of the device for air disinfection; fig. 2 is a schematic representation of the housing of the air disinfection device shown in FIG. one.

The inventive device for air disinfection according to Fig. 1 and FIG. 2 contains a housing 1 and a front part 2, which are connected by an air duct 3, as well as a source 4 of ultraviolet radiation and partitions 5 located inside the housing 1, forming circulation channels in the internal volume of the housing 1 disinfected air, while in the housing 1 (or in the walls of the housing) there is an inlet 6 for supplying air from the environment and an outlet 7 for removing disinfected exhaled air into the environment. The housing 1 contains an inner wall 8 dividing the internal volume of the housing into a chamber 9 for decontaminating inhaled air and a chamber 10 for decontaminating exhaled air. Also in the housing 1 there is a hole And for installing the air duct 3 and a hole 12 for installing the air duct 13 (Fig. 1), which connects the front part 2 and the housing 1, thus providing the supply of exhaled air by the user to the chamber 10 for disinfecting exhaled air, organized in the internal body volume 1. In FIG. 1 also shows a fan 14 mounted on the body 1 of the device, which is configured to blow air into the chamber 9 for disinfecting the inhaled air from the environment. The direction of movement of air flows in the internal volume of the housing 1 is shown by arrows in Fig. 2.

The operation of the air disinfection device is carried out as follows. The body 1 of the device is fixed, for example, on a strap, which allows it to be put on over the shoulder, and the front part 2 is put on the face, after which the device is put into action by activating the battery pack (not shown in the figures) of the ultraviolet radiation source 4 and the fan 14 , for example, by pressing the power button (not shown in the figures) on the housing 1. With the help of a fan 14, air is forced from the environment into the chamber 9 for disinfecting inhaled air, organized by installing the inner wall 8 in the internal volume of the housing 1 of the device. Circulation is thus arranged as shown by the arrows in FIG. 2 entering through the air inlet 6 through the circulation channels formed by the presence of partitions 5. At the same time, the air circulating in these channels is treated by exposure to radiation from an ultraviolet radiation source 4, for example, an ultraviolet lamp, thus disinfecting the air inhaled by the user. Further supply of decontaminated air through the air duct 3 to the front part 2, worn by the user, who inhales the disinfected air. At the same time, air exhaled by the user is supplied through the air duct 13 to the exhaled air disinfection chamber 10, organized by installing the inner wall 8 in the internal volume of the device housing 1, where the exhaled air is exposed to radiation from the source 4 of ultraviolet radiation. Mixing of inhaled and exhaled air is prevented by installing reverse valves between the air ducts 3, 13 and the front part 2. In this way, the air exhaled by the user is also disinfected before being released into the environment through the outlet 7.

Thus, a device for air disinfection has been developed, the design of which ensures the achievement of a technical result, which consists in increasing the efficiency of the device. Additional technical results achieved in the implementation of the proposed device are the simplicity, durability and mobility of the device.

It should be understood that the claimed air disinfection device as defined in the appended claims is not necessarily limited to the specific features and embodiments described above. On the contrary, the specific features and embodiments described above are disclosed as exemplary implementations of the claims, and other equivalent features may be covered by the claims of this invention.

Claims

7 Utility Model Formula

1. A device for air disinfection, comprising a housing and a front part, which are connected by an air duct, as well as a source of ultraviolet radiation and partitions located inside the housing, forming channels for circulating disinfected air in the internal volume of the housing, while the housing has an inlet for supplying air from the environment. environment and an outlet for removing decontaminated exhaled air into the environment, characterized in that the housing contains an inner wall separating the internal volume of the housing into an inhaled air disinfection chamber and an exhaled air disinfection chamber, while the partitions and the inner wall of the housing are made of a material that transmits ultraviolet radiation.

2. The device according to claim. 1, characterized in that the material that transmits ultraviolet radiation is selected from the group containing quartz glass and uvio glass.

3. The device according to claim 1, characterized in that a fan is installed on the device case, which is configured to blow air into the chamber for disinfecting inhaled air from the environment.

4. The device according to claim. 3, characterized in that it is equipped with a battery power supply source of ultraviolet radiation and fan.

5. The device according to claim. 1, characterized in that the walls of the housing are made of a material that does not transmit ultraviolet radiation.

6. The device according to claim. 1, characterized in that the source of ultraviolet radiation is installed in the chamber for disinfecting the inhaled air next to the separating partition.

7. The device according to claim. 1, characterized in that the source of ultraviolet radiation is an ultraviolet lamp. 8

8. The device according to claim. 1, characterized in that the front of the device is a mask, half mask or quarter mask.