RU183210U1 - Device for air disinfection and purification - Google Patents

Abstract

The claimed utility model relates to a device for disinfecting and purifying air with a degree of purification from bacteria, viruses, fungi and chemical contaminants of at least 99%, and is used in medical facilities of all types and public transport. The technical result of the claimed device for disinfecting and purifying air is the fact that it contains a housing with nozzles, inside of which there are disinfection and air purification elements, and a hinged lid, a network connection unit, mounting brackets I am. At the same time, buses are mounted inside the case for attaching ion generators connected to the network unit, while the power supply to the ion generator occurs simultaneously with air supply, while the network unit includes a normally closed dry contact and terminal block, and a pressure seal is made on the case In this case, ion generators generating ions of both polarities and an electron density of 10 eV of at least 70% are connected to the buses. In addition, the device contains an ozone sensor. In addition, the device contains an ozone sensor, The device contains an ozone sensor installed in the housing pipe and is connected to the network interface card. The device contains an ozone sensor installed in the housing nozzle and is connected to the network unit and the network interface card. This device contains an air quality sensor.

Description

The claimed utility model relates to a device for disinfecting and purifying air with a degree of purification from bacteria, viruses, fungi and chemical contaminants of at least 99%; it is used in medical facilities of all types and public transport.

An analogue of the technical solution proposed for patenting is a bactericidal irradiator containing a housing with lamp holders, cartridges, in which one or several low-pressure mercury lamps are connected, connected to a power supply and control unit with a ballast, according to a utility model, the power supply and control unit is additionally equipped with a unit inclusion delays. In this case, the on-delay unit can be made in the form of a time relay with an on-delay, the normally open contacts of which are included in the electrical circuit to connect to the power source - the electric network (patent for utility model of the Russian Federation No. 139908, publication date: 04/27/2014).

The bactericidal irradiator does not solve the problem of air disinfection in the presence of people, since electromagnetic radiation with a wavelength of 250 nm causes burns to the skin and eyes, which is the main and significant drawback.

A prototype of the claimed utility model is an ultraviolet device 100 for use in a duct or duct 10 of a ventilation system, which preferably has a separation panel 1; an electronic module 2 for storing ballast and electronic components is mounted on the outside of the separation panel 1; an irradiation module 5, consisting of a bactericidal lamp 3 in a substantially parabolic reflector 4, a reflector 4 having an opening 43 for passing filtered air from the air filter module 6, the lamp 3, the reflector 4, and the air filter module 6, is supported on the inside of the separation panel 1 and in which when assembling to the pipe 10, the irradiation device device 100 is passed into the hole 9 cut in the pipe 10 until the dividing panel 1 can close the hole 9 and is attached to the pipe oprovodu 10, thereby positioning the exposure unit 5 and the filter unit 6 in the air path or the air conduit 10 (U.S. Patent invention №US2008279733 (A1), publication date: 2008-11-13 g).

The prototype uses an ultraviolet lamp F15 T8 with a power of 15 watts. In this case, the device can handle only 30 m ³ / h of air. It follows that this technology is an order of magnitude less energy efficient. Gas discharge lamps have an efficiency of 60%, while only part of the energy goes to the formation of the desired radiation spectrum, the rest of the radiation is absorbed by the protective layer of the lamp or does not have an effect on pathogens, i.e. the device is less effective in disinfecting and purifying air.

The technical result proposed for patenting a utility model is to increase the efficiency in disinfection and purification of air with a degree of purification from bacteria, viruses, fungi and chemical contaminants of at least 99%.

The achieved technical result of the claimed device for disinfection and purification of air is that it contains a housing with nozzles, inside of which there are elements of disinfection and purification of air, and a hinged lid, network unit, mounting brackets. At the same time, buses are mounted inside the case for attaching ion generators connected to the network unit, while the power supply to the ion generator occurs simultaneously with air supply, while the network unit includes a normally closed dry contact and terminal block, and a pressure seal is made on the case .

In this case, ion generators that generate ions of both polarities and with an electron density of 10 eV of at least 70% are connected to the buses.

In this case, the device contains an ozone sensor.

Moreover, the device contains an ozone sensor installed in the pipe of the housing, connected to a network unit.

At the same time, the device contains an ozone sensor installed in the housing pipe, connected to the network interface board.

At the same time, the device contains an ozone sensor installed in the housing pipe, connected to the network unit and the network interface board.

In this case, the device contains an air quality sensor.

At the same time, the device contains an air quality sensor installed in the housing pipe, connected to the network unit.

At the same time, the device contains an air quality sensor installed in the housing pipe, connected to the network interface board.

At the same time, the device contains an air quality sensor installed in the housing pipe, connected to the network unit and the network interface board.

The claimed utility model is illustrated in the drawing.

In FIG. 1 shows a General view of the device in longitudinal section.

Where, 1 - housing, 2 - ion generator; 3 - tire; 4 - network block; 5 - pipe; 6 - network interface card; 7 - pressure seal; 8 - air quality sensor; 9 - ozone sensor; 10 - bracket for mounting the device.

A device for disinfecting and purifying air consists of a housing (1) with tires installed in it (3), made, for example, of metal with nuts, for example, welded to the housing, for attaching one or more ion generators to them (2) , for example, with screws connected to the network unit (4). In this case, the power supply to the ion generator (2) occurs simultaneously with the air supply.

For example, a normally open dry contact is established in the fan’s power board, which closes when voltage is applied to the fan, providing voltage to the device.

The network unit (4) includes a normally closed dry contact and a terminal block. Air supply to the device is carried out through a pressure seal.

Any direction of air through the nozzles (5) is allowed. It is allowed to connect ion generators to buses (3) that generate ions of both polarities and with an electron density of 10 eV at least 70%.

The device can be equipped with an ozone sensor and an air quality sensor, for example, VOC (particles).

The sensors are installed in the pipe (5) of the housing (1).

The ozone sensor (9) is connected to the network unit (4) and the network interface board (6) or can be connected separately to both the network unit (4) and the network interface board (6).

The air quality sensor, VOC, is connected to the network unit and network interface board (6) or can be connected separately to both the network unit and the network interface board.

The device is as follows.

The device for disinfecting and purifying air is connected to the ventilation network through the pipes (5) of the case (1), the power supply is supplied to the network unit (4) and must be connected to a fan (not included in the device), which can be installed anywhere ventilation network. The ventilation network consists of various elements (fans, filters, air ducts, anemostats) and the claimed device is one of these elements. For example, in a subway car, this is a fan that provides ventilation for the car. In operating rooms, this is a complete ventilation unit, usually located in the ventilation chamber.

The air flow driven by the fan passes through the housing (1), is cleaned and disinfected by ion generators (2). Supply air is supplied from the supply chamber, where it is pre-treated to the required regulatory parameters for temperature and humidity, for example, 22 ° C and 45%.

The treated supply air, passing through the device, is ionized, forming free radicals of water vapor (O2- and OH-), which are super active to any organics, converting it to water, carbon dioxide and protein compounds. Due to the high electron charge of about 12 eV, it is possible to create cluster chains of water molecules capable of interacting with contaminants for 1 s, which makes it possible to clean not only air, but also remove pathogens from HEPA filters.

The efficiency of the device can be monitored at a remote control room by installing a VOC air quality sensor that transmits the content of particles in the air after the device via a network interface board (6). The increased amount of particles in the air indicates that the ion generators must be cleaned of dust or replaced. During the operation of the device, a certain amount of ozone is generated and in the event of a fan failure, the amount of ozone can exceed the maximum permissible concentration (MPC), for signaling and emergency shutdown of the device an optional ozone sensor is proposed, which, if the MPC is exceeded by ozone, opens the dry contact of the network unit ( 4) and thus disconnects the device from the mains. Using the network interface board (6), the ozone sensor can transmit information about the ozone content in the air after the device to a remote control room.

The test results of the device are shown in Table 1.

The operation of the prototype confirmed the influence of a set of essential features on the achieved technical result: increased efficiency in disinfection and air purification with a degree of purification from bacteria, viruses, fungi and chemical contaminants of at least 99%.

The utility model is new, since the entire set of features is not known from the prior art described in the corresponding section of the description, as well as industrially applicable in the used technical field.

Claims (2)

1. A device for disinfecting and purifying air, comprising a housing with nozzles, inside of which there are elements of disinfecting and air purification, and a hinged lid, a network unit, mounting brackets for the device, characterized in that the busbars for mounting ion generators that are used inside are installed as disinfection and air purification elements connected to the network unit, while the power supply to the ion generator occurs simultaneously with the air supply, while the network unit includes but mally closed dry contact and terminal block, wherein the housing is configured germovvod, the apparatus has a network interface card. 2. The device for disinfecting and purifying air according to claim 1, characterized in that ion generators that generate ions of both polarities are connected to the buses, and generation occurs at an electron density of at least 70%, while the electron energy is 12 eV.

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