RU2758127C1 - Individual uv screen-type recirculator - Google Patents

Abstract

FIELD: medical technology.

SUBSTANCE: invention relates to medical technology, namely to an individual UV screen-type recirculator. The recirculator includes a transparent curved screen with a mounting module. A filter module is inserted into it, fixed on the inner surface of the transparent screen and containing a housing with an internal cavity in which an ultraviolet radiation source is installed, on which at least one fan is fixed, coupled to the inner cavity by means of at least one inlet. The housing contains at least one outlet, and the surface of the inner cavity of the housing is covered with a layer of titanium dioxide. Partitions are installed in the inner cavity, made with the possibility of increasing the length of channels between at least one inlet and at least one outlet. The partitions are covered with a layer of titanium dioxide. A fan speed controller and a switch for operating modes of the ultraviolet radiation source are introduced into the recirculator. A porous material coated with a layer of titanium dioxide is applied to the inner surface of the transparent screen. The partitions are covered with a layer of titanium dioxide with a thickness in the range of 0.1-2 mcm.

EFFECT: invention makes it possible to increase the degree of protection against bacteria and viruses.

3 cl, 2 dwg

Description

The invention relates to the field of protective devices, primarily of the respiratory system against bacteria and viruses.

Known protective mask for the face, containing a protective screen, a fixation unit on the head, a unit for attaching the screen to the fixation unit, and the fixation unit is made in the form of a hoop and consists of a rigid arc and a soft belt connected to each other, while the screen is fixed directly on the hoop, and elements of the fixation unit are fastened together by means of an adhesive bond. There are variants of this device, in which the belt is equipped with a lock with the ability to adjust the length of the belt, the screen is fixed on the hoop with an adhesive connection or rivets with the possibility of rotating the screen relative to the fixation unit. There is also a variant in which the fixing unit is provided with a stop made in the form of triangular overlays with the possibility of interacting with the screen in the lowered and raised positions. There is also a variant in which the hoop is supplemented with screen holders, one end of each holder being movably fixed to the hoop, and the screen is attached to the second by means of an adhesive joint (PM RU 18915 U1).

The disadvantage of this device is that it has no filtration means and cannot be used to protect against bacteria and viruses.

It is also known a protective device for the face, containing the element covering the head and a protective screen made of transparent material (application EP 0338581). The screen can be lifted upwards thanks to the articulated connection. Also known is a face mask comprising a rigid frame attached to the headband by means of tabs and a semi-cylindrical thin transparent film stretched over the frame (GB 2215584). Both of the above-described devices are fixed on the head with a rigid fastening element, which creates certain inconveniences in operation. However, they also lack filtration means and cannot be used to protect against bacteria and viruses. There is also a protective face mask, which is a flat, crescent-shaped semi-rigid element and a transparent element covering the face (US patent 4852185). The mask is fixed to the user's forehead with an elastic element. A significant disadvantage of this design is the difficult use of this mask for people using glasses for vision correction. However, it also lacks filtration and cannot be used to protect against viruses and bacteria. Also known is a protective face mask, which belongs to the field of medicine and relates to protective devices used in the work of doctors. The technical result of the invention is to increase the degree of protection of the face, mouth, hearing, vision and breathing of doctors from the effects of harmful factors for health, such as noise, eye strain, dust, the risk of transmission of pathogenic bacteria and viruses from patients. The protective mask contains a transparent screen connected to a rigid attachment element consisting of a thin arc with a screen holder. Elements with the possibility of freedom of movement along the arc are located on the temples. There are clips for corrective lenses, the removable screen has a thickness of 0.5 - 1.0 mm, the lower part of the screen has a parabolic shape (patent RU 2141810).

The disadvantage of this device is that it lacks filtration means and has limited capabilities to protect against bacteria and viruses. This device was chosen as a prototype of the proposed solution.

The technical result of the invention is to increase the degree of protection against bacteria and viruses.

The technical result of the invention lies in the fact that in an individual screen-type ultraviolet recirculator, including a curvilinear transparent screen with a fastening module, a filter module is introduced, fixed on the inner surface of the transparent screen and containing a housing with an internal cavity, in which an ultraviolet radiation source is installed, on which at least one fan is fixed, coupled with the inner cavity by means of at least one inlet, the housing containing at least one outlet, and the surface of the inner cavity of the housing is coated with a layer of titanium dioxide.

There is an option in which the UV radiation source is made in the form of a matrix of UV LEDs.

There is also a variant in which the housing includes two outlet openings located opposite at least one fan and symmetrically relative to it along the edges of the housing.

There is also a variant in which partitions are installed in the inner cavity, providing an increase in the length of the channels between at least one inlet and at least one outlet, while the partitions are covered with a layer of titanium dioxide.

There is also a variant in which a fan speed controller is introduced into the device.

There is also a variant in which a switch for operating modes of the UV source is introduced into the device.

There is also a variant in which a porous material coated with a titanium dioxide layer is applied to the inner surface of the transparent screen.

FIG. 1 shows an individual UV screen-type recirculator.

FIG. 2 shows a view A according to FIG. 1.

An individual UV recirculator of the screen type includes a transparent screen 1 (Fig. 1, Fig. 2) of curved shape with a fastening module 2. Any transparent plastic can be used as a transparent screen 1. An elastic belt or a belt with a magnetic length adjuster (not shown) can be used as the attachment module 2. On the inner surface of the transparent screen 1, a filtering module 3 is fixed, containing a housing 4 with an internal cavity 5. Any type of plastic, both thermosetting and thermoplastic, can be used as the material of the housing 4. And in a particular case, you can use a light metal, such as aluminum or titanium. The fastening of the filter module 3 to the screen 1 can be carried out using screws or fixing clamps (not shown). A source of ultraviolet (UV) radiation is installed in the inner cavity 5. At least one fan 7 is fixed on the housing 4, which is coupled to the inner cavity 5 by means of at least one inlet 8. Small-sized fans can be used as the fan 7 by Jntel. The body 4 contains at least one outlet 9 located on the opposite side from the inlet 8. In this case, the surface of the inner cavity 5 of the body 4 is coated with a layer of titanium dioxide 10, with a thickness in the range of 0.1 µm - 2 µm.

There is an option in which the source of ultraviolet radiation 6 is made in the form of a matrix 11 of ultraviolet LEDs 12 with a wavelength of 250 nm - 280 nm. The UV LEDs 12 can be arranged in a single row as indicated in FIG. 1, or - in several rows (not shown). As ultraviolet LEDs 12 can be used, for example, LEDs RC35EO-UBE-AR with a wavelength of 350 nm - 370 nm with a power of 20 mW - 50 mW.

There is also a variant in which the housing 4 includes two outlet openings 9 located opposite at least one fan 7 and symmetrically relative to it along the edges of the housing 4. This variant is most preferable.

There is also a variant in which partitions 13 are installed in the inner cavity 5, which provide an increase in the length of the channels between at least one inlet 8 and at least one outlet 9. The same material can be used as the material of the partitions 13, as the body material. The baffles 13 are also coated with a titanium dioxide layer with a thickness in the range of 0.1 µm - 2 µm. The partitions 13, in one of the variants, are installed in the housing 4 without the possibility of being removed using glue, or by press fit. A variant is also possible in which the partitions 13 are installed in the housing 4 with the possibility of being removable for preventive cleaning. In this case, they can be installed in the housing 4, for example, with an interference fit, or using eccentric (or other) clamps (not shown).

There is also a variant in which the speed controller 14 of the fan 7 is introduced into the device. The thyristor controller can be used as the speed controller 14.

There is also a variant in which a switch 15 of the operating modes of the ultraviolet radiation source 6 (ultraviolet LEDs 12) is introduced into the device. In one embodiment, there may be a full power mode and a half power mode of the UV source 6. Any small-sized pushbutton switch can be used as the switch 15.

The speed controller 14 and the switch 15 are connected to a control unit 16, which includes a converter and a voltage stabilizer and a control microcircuit.

A variant is possible in which a cover 17 is fixed on the housing 4, which can be removed for operational prevention of the device. The cover 17 can be fixed to the housing 4 by means of screws (not shown).

On the matrix 11, on the opposite side from the ultraviolet LEDs 12, radiators 18, made, for example, of an aluminum alloy, can be installed.

There is also a variant in which a porous material 19 is applied to the inner surface of the transparent screen 1, which can be porous polyethylene coated with a titanium dioxide layer 0.1 µm - 2 µm thick.

A power supply unit 20, made in the form of a box (for example, for a battery), with a cover (not shown) can be fixed on the fixing module 2. In this case, the fastening module 2 can be fixed on the filtering module 3 using the detachable hooks 21.

The device works as follows.

After fixing the device on the head of a person, the fan 7 is turned on and the required rotation speed is set using the speed controller 14. This speed can be determined by both the comfortable operating conditions of the device and the level of potential danger. The higher the danger, the higher the rotation speed can be set on the fan 7. After that, using the switch 15 set the required mode of operation of the ultraviolet LEDs 12. This mode can also be determined by the level of potential danger. The higher the danger, the more power can be supplied to the ultraviolet LEDs 12. The pumped air enters from the environment through the inlet 8 into the internal cavity 5 of the housing 4. Further, bypassing the partitions 13, the disinfected air through the outlet openings 9 enters the space between the human respiratory organs and a transparent screen 1. Disinfection of air coming from the environment occurs by radiation from ultraviolet LEDs 12 in the inner cavity 5, as well as on the surface of titanium dioxide, the inner cavity 5 of the housing 4, partitions 13 and the inner surface of the transparent screen 1 stimulated by ultraviolet radiation. The process of air disinfection on titanium dioxide, including when exposed to ultraviolet radiation (see "Light and titanium purify water and air", Science and Technology News, 09.02.2020, nkj.ru, news 38110).

The fact that in an individual screen-type ultraviolet recirculator, including a curved transparent screen 1 with a fastening module 2, a filter module 3 is introduced, fixed on the inner surface of the transparent screen 1 and containing a housing 4 with an inner cavity 5, in which an ultraviolet radiation source 6 is installed, on which is fixed at least one fan 7, coupled with the inner cavity 5 by means of at least one inlet 8, while the housing 4 contains at least one outlet 9, and the surface of the inner cavity 5 of the housing 4 Coated with a layer of titanium dioxide 10 increases the degree of protection of the device against bacteria and viruses. This is achieved through the use of an ultraviolet radiation source 6, which destroys bacteria and viruses, and activates the interactions of titanium dioxide not only with bacteria and viruses, but also with organic odors. In this case, the degree of deactivation of bacteria, viruses and odors can be more than 99%.

The fact that the source of ultraviolet radiation 6 is made in the form of a matrix 11 of ultraviolet LEDs 12 increases the uniformity of the UV light flux, which creates optimal conditions for the destruction of bacteria and viruses over a larger area of the titanium dioxide layer, as well as directly in the UV radiation stream.

The fact that the housing 1 includes two outlet openings 9 located opposite at least one fan 7 and symmetrically relative to it along the edges of the housing 4 leads to an optimal distribution of the cleaned air around the respiratory organs of the protected person. At the same time, the penetration of air from the external environment under the transparent screen 1 is reduced.

The fact that partitions 13 are installed in the inner cavity 5, covered with a layer of titanium dioxide and providing an increase in the length of the channels between at least one inlet 8 and at least one outlet 9 leads to an increase in the cross section of interaction of the supplied air with titanium dioxide, and, consequently, increases the degree of purification of the air supplied for inhalation.

The fact that the speed controller 14 of the fan 7 is introduced into the device makes it possible to create comfortable conditions for the operation of the device, as well as to regulate the degree of purification of the air supplied for inhalation, depending on the level of potential danger.

The fact that a switch 15 of the operating modes of the ultraviolet radiation source 6 is introduced into the device leads to the optimization of the operation of the device, tk. allows you to adjust the operating mode of the device for a specific external situation and the level of potential danger.

The fact that the inner surface of the transparent screen 1 is coated with a porous material 19, on which a layer of titanium dioxide is applied, leads to an increase in the surface of interaction of titanium dioxide with ultraviolet radiation and purified air. And this, in turn, increases the speed of air purification and the degree of its purification.

Claims (3)

1. Individual ultraviolet screen-type recirculator, including a curved transparent screen with a fastening module, and a filter module is introduced into it, fixed on the inner surface of the transparent screen and containing a housing with an internal cavity, in which an ultraviolet radiation source is installed, on which it is fixed, according to at least one fan coupled to the inner cavity by means of at least one inlet, wherein the housing contains at least one outlet, and the surface of the inner cavity of the housing is coated with a titanium dioxide layer, and baffles are installed in the inner cavity , made with the possibility of increasing the length of the channels between at least one inlet and at least one outlet, while the partitions are covered with a layer of titanium dioxide, a fan speed regulator and a switch for operating modes of the ultraviolet source are also introduced into the recirculator In this case, a porous material coated with a layer of titanium dioxide is deposited on the inner surface of the transparent screen, while the partitions are covered with a layer of titanium dioxide with a thickness in the range of 0.1–2 µm. 2. The device according to claim. 1, characterized in that the source of ultraviolet radiation is made in the form of a matrix of ultraviolet light-emitting diodes. 3. The device according to claim. 1, characterized in that the housing includes two outlet openings located opposite at least one fan and symmetrically relative to it along the edges of the housing.

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