RU188578U1 - Installation for air disinfection - Google Patents

Abstract

The invention relates to transport engineering and can be used for disinfecting air in the systems of supply and exhaust ventilation and air conditioning of passenger rail transport, as well as in other types of public transport. In the installation for air disinfection with ultraviolet radiation, including a T-shaped in a vertical cross-section of the case with a hatch in the lower part of the case located on the sides at the ends of the horizontal part of the case inlet windows for air flow and an outlet window for air flow located in the upper part on the end the vertical part of the housing, mounted in the housing, at least one lamp assembly with at least one ultraviolet lamp located inside the housing, with vibration damping elements, input The exit and exit windows are provided with protective grilles, the lamp unit is made in the form of a rectangular duct mounted on the body wall by means of a detachable connection, on one of the walls of which the vibration-suppressing elements with a lamp are located on the side of the internal cavity of the body; the walls of the box and connected to the cable electrical connector located outside the housing. The utility model will simplify the maintenance of the device.

Description

The invention relates to transport engineering and can be used for disinfecting air in the systems of supply and exhaust ventilation and air conditioning of passenger rail transport, as well as in other types of public transport.

One of the requirements for structures intended for use in railway transport are vibration resistance and a high degree of protection from external influences - from dust, which is a combustible substance, and from moisture. Air disinfection systems must ensure that the level of contamination of air by microorganisms is epidemiologically safe for passengers in accordance with sanitary and hygienic standards.

A bactericidal irradiator is known for disinfecting air and indoor surfaces, comprising a housing with inlet and outlet windows, closed louvers, in which a fan and UV sources are installed, low-pressure mercury lamps installed along the air flow are used as the UV source , the inner walls of the housing have a reflective coating (RU 38610 U1, 07/10/2004)

The known irradiator is provided with a means of protection against UV radiation, which is louvered grilles consisting of a frame and blackened V-shaped profile elements mounted in a frame with the formation of narrow labyrinth gaps between them, which eliminates the reflection of UV rays from the surface of louvered grilles and exit to the outside. In the case there is a hatch, which provides different modes of operation of the irradiator.

The irradiator has a high bactericidal efficiency of air disinfection, however, its design does not allow the use of an irradiator in transport, because its design does not meet the technical requirements established for the railway

Known installation for disinfecting air by UV radiation, comprising a housing with a hatch, an entrance window, closed by a protective grille formed by the profile elements, the surface of which is coated, the exit window and fixed inside the housing, at least one ultraviolet lamp, on the case of the installation stiffening ribs, and the ultraviolet lamp is fixed by means of vibration damping elements (RU 78074 U1, 20.11.2008).

The disadvantage of this design is that in this installation for each connector of the UV lamp there is a separate lamp assembly, in this construction the assembly - disassembly of the lamp assembly and lamp replacement are labor-intensive processes, which complicates the maintenance of the device.

Closest to the declared is the installation for disinfecting air by UV radiation in electric train cars, including a housing equipped with a hatch and having stiffening ribs with an inlet and outlet window for air flow, inside of which at least one UV lamp is fixed, fixed by means of vibration-damping elements; a protective grid formed by profile elements, on the surface of which a photocatalytic coating based on titanium dioxide is applied, mounted on the inlet window, the installation body is made with a T-shaped cross section formed by horizontal and vertical protrusions, and has an additional input window; the entrance windows are located on the sides of the horizontal protrusions of the housing, and the exit window in the upper part of the vertical protrusion, moreover, protective grilles are installed on both the entrance and the exit windows (RU 143645 U1, 07.27.2014).

The installation is compact and its design takes into account the particular configuration of the electric train's air duct, ensures the epidemiological safety of passengers en route due to effective UV disinfection of recirculating air.

The disadvantage of this known construction is that this installation for each connector of the UV lamp has its own separate lamp assembly consisting of a stainless steel glass made by the method of sequential extrusion, a bellows, and a sleeve made by turning the fluoroplastic-4 (the bellows and the sleeve) are designed to damping the vibrations transmitted from the car to the UV lamp) and the connector for connecting the UV lamp to the junction box (designed to connect the ignition units, control and monitor the UV lamps and the UV itself lamps with control system and power supply of the car). Thus, the UV module was connected to the junction box by means of 4 cables. Therefore, in this construction, installation - disassembly of the lamp assembly and replacement of lamps are labor-intensive processes, which complicates the maintenance of the device.

The technical result of the proposed utility model is to eliminate these drawbacks, simplify the maintenance of the device by simplifying the installation and dismantling of the lamp assembly and the replacement of UV lamps.

This technical result is achieved due to the fact that in the installation for air disinfection with ultraviolet radiation, including a T-shaped case in a vertical cross section with a hatch in the lower part of the case, located on the sides at the ends of the horizontal part of the case as inlet windows for air flow and an exit window for air flow, located in the upper part at the end of the vertical part of the housing, mounted in the housing, at least one lamp assembly located inside the housing, at least , one ultraviolet lamp with vibration-suppressing elements, inlet and outlet windows are provided with protective grilles, the lamp unit is designed as fixed on the housing wall by means of a detachable connection of a rectangular box, on one of which walls there are vibration damping elements with a lamp from the inside of the housing; located in the cavity formed by the inner and outer walls of the box and connected to the cable electrical connector located outside the housing.

In addition, the protective lattices are made with a coating in the form of a layer of photocatalyst based on titanium dioxide.

In addition, the ultraviolet lamps in the installation case are placed one above the other in such a way that the bend of the bulb of one lamp is opposite the basement part of the other lamp.

The utility model is illustrated by drawings, where in FIG. 1 shows an installation for air disinfection, front view; figure 2 is the same, side view; figure 3 is the same, top view; in fig. 4 - the same, bottom view; FIG. 5 is a section A-A in FIG. 1: FIG. 6 is view B in FIG. 5; in fig. 7 is a section of D-D in FIG. 2; in fig. 8 is a section of the EE of Fig.7.

. Installation for air disinfection with ultraviolet radiation includes a T-shaped in cross section case 1 with a hatch 2 in the lower part of the case 1, located on the sides at the ends of the horizontal part of the case 1, the input window 3 for air flow and the output window 4 for air flow located in the upper parts on the end of the vertical part of the housing 1.

In the housing 1 lamp assemblies 5 are mounted with ultraviolet lamps 6 located inside the housing 1 with vibration damping elements 7.

UV lamp 6 in the housing 1 installation placed one above the other in such a way that the bend of the bulb of one lamp 6 is opposite the basement part of the other lamp 6.

Input and output windows 3 and 4 are equipped with protective grills 8 and 9, respectively.

The lamp unit 5 is made in the form of a rectangular box 11 fixed to the wall of the housing 1 by means of a plug-in connection 10 with the inner and outer walls 12 and 13, respectively.

Anti-vibration elements 7 with a lamp 6 are located on one of the walls 12 of the box 11 from the side of the internal cavity of the housing 1.

 Wires 14 from the ultraviolet lamp 6 are located in the cavity 18 formed by the inner and outer walls 12 and 13 of the box 11 and are connected to the cable electrical connector 15 located outside the housing 1.

Protective grilles 8 and 9 are mounted of profile elements, the shape of which does not allow to allow the output of UV radiation from the housing 1 and allows you to protect other structural elements of the duct from the effects of UV radiation, reducing their service life. Protective lattices 8 and 9 are made with a coating in the form of a layer of photocatalyst based on titanium dioxide, which further enhances the effect of disinfection and air purification through the process of photocatalysis.

One or more ultraviolet lamps 6 are installed inside the housing 1 across the air flow in vibration-resistant mounts with vibration damping elements 7.

The vibration damping elements 7 include a fluoroplastic bellows 16, a spring 17 and a rubber sealing ring 19, which are designed to dampen vibrations transmitted to the lamp 6 as the train car moves.

On the bottom of the housing 1 there is a hatch 2 for access to the UV lamps 6.

The device works as follows.

      The system of ventilation and air conditioning of a passenger electric train car is formed by an air conditioner located on the roof of the car, as well as inlet and recirculation channels that run along the under-roof space of the car and are fenced from the cabin by a perforated ceiling. Intake of infected air from the passenger compartment through the side recirculation channels. Next, the recirculated air enters the air conditioner, where it mixes with the outside fresh air. After passing the air flow through the air conditioner, the air through the perforated ceiling comes back to the salon.

The UV air disinfection unit is built into the recirculation channel of the passenger car ventilation and air conditioning system. The flow of recirculated air infected with microorganisms enters from the car through the entrance windows 3 to the UV irradiation zone, where under the action of the bactericidal radiation of the UV lamps 6 it is disinfected and cleaned.

Air enters the entrance window 3 through the protective grid 8, passes by the llamas 6 and through the grid 9 of the exit window 4 exits.

The treated air is removed through the output window 4, and through the fan of the air conditioner is fed into the compartment of the car. To exclude the output of UV radiation, protective grilles 8 and 9 are formed by elements of a special profile (for example, as in patent RU 45273 U1, 23.11.2004), on the surface of which a photocatalyst layer is applied, which is titanium dioxide in the anatase phase.

Lamps 6 are fixed by means of vibration-damping elements 7, the flasks being installed in brackets bent at the bend in the form of a propeller (not shown), and lamp caps in the vibration-damping bellows.

The lamp emergency shutdown sensor is triggered when the lamp overheats at 60 ° C.

With the passage of air past the lamp 6 and through the grill 8 and 9 air disinfection occurs. When the air passes by the lamp 6 disinfection occurs due to the inactivation of microorganisms as a result of the appearance of thymine dimers in DNA under the influence of UV radiation with a wavelength of 253.7 nm, which leads to the termination of the DNA replication process, in other words, the microorganism loses its ability to reproduce. When passing through the 8.9 lattices, disinfection occurs due to two processes: the first process occurs on the surface of titanium dioxide coated plates in anatase modification, when UV radiation enters the surface of the plates, photocatalytic reactions occur which lead to the destruction of microorganisms touching the surface of the plates, the second process occurs volume - as a result of photochemical reactions on the surface of the plates, in the passing air hydroxyl radicals are formed which are a strong disinfectant.

The treated air is removed through the output window 4, and through the fan of the air conditioner is fed into the compartment of the car. As a source of bactericidal UV radiation, two powerful, zoneless low-pressure amalgamic low-pressure lamps ANC 215/95, U-shaped, specially designed for air treatment are used.

(RU 2325727 C1, 05/27/2008).

The start-up and adjustment of the UV lamps 6 is carried out by means of an electronic control device electrically connected to it (not shown in the drawings).

The installation provides a disinfection efficiency of 99.99% with a capacity of about 3000 m ³ / h.

Performing a lamp assembly in the form of a removable single box allows for quick and easy installation, removal and connection to the power supply of the lamp assembly in the device and replacement of ultraviolet lamps. All signs of the independent claim are essential and are aimed at achieving the specified technical result.

The utility model will thus simplify the maintenance of the device.

Claims (3)

1. Installation for air disinfection by ultraviolet radiation, including a T-shaped case in cross section with a hatch in the lower part of the case, located on the sides at the ends of the horizontal part of the case by inlet windows for air flow and an outlet window for air stream located in the upper part on the end vertical part of the housing, mounted in the housing, at least one lamp assembly with at least one ultraviolet lamp located inside the housing, with vibration damping elements, input and output The window is provided with protective grids, characterized in that the lamp assembly is made in the form of a rectangular duct mounted on the housing wall by means of a plug connection, on one of the walls of which from the inside of the housing are vibration damping elements with a lamp from which wires are located in the cavity formed by the inner and the outer walls of the box and connected to the cable electrical connector located outside the housing. 2. Installation under item 1, characterized in that the protective lattice is made with a coating in the form of a layer of photocatalyst based on titanium dioxide. 3. Installation according to claim 1, characterized in that the UV lamps in the installation case are placed one above the other in such a way that the bend of the bulb of one lamp is opposite the basement part of the other lamp.

Images