RU2750411C1 - System for implementation of nonspecific prophylaxis of shoe soles disinfection, device for processing the soles of shoes for this system and method for nonspecific prophylaxis of shoe soles disinfection - Google Patents

Abstract

FIELD: shoe soles disinfection.SUBSTANCE: invention relates to a device for treating shoe soles for a system for implementing non-specific prophylaxis for disinfection of shoe soles, and it comprises a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface on which people move, a hollow frame is installed in the bath cavity with hollow longitudinal and transverse elements communicated with the pump for pumping out the disinfectant solution and in the upper parts of which there are through holes for draining the excess of this liquid, nozzles for supplying a clean disinfectant solution into the bath cavity, which are in communication with the pump for supplying this liquid to the specified nozzles, and at least one optical sensor for monitoring the level of the disinfectant solution above the grate level.EFFECT: ensuring prompt and guaranteed high-quality disinfection of the shoe soles of a person entering or leaving the premises, while excluding him from stopping in motion due to wet processing of the sole with a disinfectant.10 cl, 8 dwg

Description

The invention relates to sanitary and hygienic means, in particular to devices and methods for non-specific prophylaxis of disinfection shoe soles. The invention can be used in the medical industry, the pharmaceutical industry, in the production of cosmetics, in the biomedical, food, semiconductor and aerospace industries, in the field of civil defense, in "clean" rooms, in data storage centers, etc.

According to foreign infectious disease specialists, one of the main surfaces that come into contact with viruses on the streets and in public places is the sole of people's shoes, on which viruses can (based on research in California) be retained for up to 5 days and actively spread by air in public buildings. A high concentration of pathogenic microorganisms on shoes occurs due to constant contact when walking on the streets, where there are much more factors and carriers of infections on the surface of the sidewalks and their concentration is extremely high. Up to 400,000 pathogens can be found on the sole of just one pair of shoes. Most of the soles have artificial materials that absorb many pathogens (microorganisms, fungi, viruses, bacteria) and are an ideal breeding ground for them.

In this case, up to 90% of pathogens are transmitted from soles to tiles, carpet or parquet when a person enters public buildings. Then, hitting the floor, these microorganisms gradually spread throughout all rooms by air currents, air conditioners and drafts, and in the form of fine dust (up to 5 microns) enter the respiratory system of people. To a lesser extent, there is also a contact method of transmission, when, first on the floor, a microbe, viruses, etc., gradually move from the floor to backpacks, briefcases, women's bags, boxes of drinks, etc., which people temporarily put or put on the floor, in order to then shift on a chair, table, place in the refrigerator, etc. And from there, the way into the human body through the mouth or nose is already close. Disinfecting the soles of your shoes has the same positive hygienic effect as washing your hands.

That is why, as part of preventive disinfection, among other measures, it is necessary to treat the soles of people's shoes with disinfectants after they are on the streets and, above all, when entering public buildings with a large crowd of people (civil defense structures of medium and large capacity, medical institutions, airports, train stations, schools, universities, supermarkets, etc.). It also requires processing at the entrance and exit from special rooms, areas, industries; for example, "clean" rooms, "red" zones of hospitals, etc.

So, there is a known method of processing in a steam aerosol substance, used in China, according to which the shoes of everyone entering a public building are treated by supplying a disinfectant in a steam aerosol substance from a steam generator to a height of up to 0.5 m.This solution (airborne method) has a number of significant disadvantages:

- the pedestrian does not see where he is going, which can lead to injury (especially if there is an obstacle);

- aerosol at this level can get into the respiratory system of small children (you need to take it out of the stroller and take it in your arms);

- this method of processing with an aerosol substance turns out to be ineffective in practice, because aerosol is dispersed by wind or draft in vestibules and passages to public buildings.

- low reliability of operation of steam generators based on ultrasound and strongly dependent on the thickness of the liquid film (up to 1 mm).

There is no film thickness control in Chinese systems.

For prevention, disinfecting mats are also used.

For example, a disinfection mat is known containing a mat impregnated with a disinfectant, around the perimeter of which a strip of waterproof fabric is sewn (US 6258435).

Also known is a mat for disinfection, containing an absorbent layer made in the form of a mat impregnated with a disinfectant, located between the moisture-proof and moisture-permeable layers, while the moisture-proof layer is a substrate having a base and side sides configured to cover at least part of the absorbent layer ( RU 71304).

There is a known device "disinfection mat" according to RU 80103, which contains a waterproof layer formed by the base and side walls, a mat placed on the base, impregnated with a disinfectant or drug, a net laid over the mat and attached to the side walls of the waterproof layer, and a board attached to the upper parts of the side walls around the perimeter of the mat. In this case, the height of the side walls of the base of the moisture-proof layer is made not less than the thickness of the mat; the board is made with an internal cavity, inside which a cord is placed, and the mat is made of recycled polyurethane foam, and on the second, the disinfection mat contains a waterproof layer formed by the base and side walls, a mat placed on the base, impregnated with a disinfectant or drug, a mesh laid on top mat and attached to the side walls of the waterproof layer, while a board is attached to the upper parts of the side walls around the perimeter of the mat, and between the mat and the mesh around the perimeter of the mat there are four waterproof strips attached to the side walls of the waterproof layer and to the mesh and interconnected by waterproof seams ...

From RU 2259803, a disinfection mat is known having an upper surface intended for contact with the soles of a person's shoe and an anti-slip base part connected to the upper part to prevent slipping when wet. The top and base of the mat contain disinfectants. In this case, the sticky and base parts can be made of both water-absorbing and water-repellent material (polyurethane foam, rubber, etc.) and with the ability to wet the soles of shoes with a disinfectant solution.

Known is a mat that includes a base that is in contact with the floor, and a removable (disposable) pad, the upper layer of which is made of absorbent material, and the lower layer, which is a barrier to the base, is made of moisture resistant material (US 6458442).

Known disinfection mat, which includes a base of flexible material (rubber or polymer) to retain moisture, the upper pile of synthetic fibers (for example, nylon), impregnated with a disinfectant solution (substance), and the bottom rims (for example, rubber or polymer) to prevent slippage (RU 59953).

Also known is the device "Disinfection mat" (patent of Ukraine No. 84506), which is made in the form of a sealed container, the lower and side walls of which are made of their chemically resistant waterproof material and are tightly connected to each other, and the upper wall, which is connected to the side walls, is flexible waterproof. In this case, a porous filler is placed between the upper and lower walls, which is impregnated with a disinfectant, the upper wall contains holes with a diameter of 0.1-0.5 mm and a diameter of 1-10 mm, which alternate with each other. The device provides cleaning and disinfection of the soles of shoes when passing over the mat without allocating special time for cleaning the shoes, since the effect of the mat is manifested only when its surface is influenced by gravity in this particular case - the weight of a person in the shoe.

The well-known and widespread means of disinfection of shoe soles due to the use of disinfectant mats have the following significant disadvantages:

- lack of methods to control the adequacy of the disinfectant, as well as its suitability (concentration and purity);

- the need for frequent cleaning of disinfectant mats, replacement, addition of liquid and other manual operations;

- the period of validity of disinfecting mats (as well as impregnated spread fabric materials) does not exceed 10 minutes. with a high intensity of pedestrian traffic.

- when dry, disinfecting mats themselves are concentrators of pathogens and viruses, which leads to the opposite effect in the form of airborne distribution of suspended particles, including a virus (when mechanically acting on a dry or dried mat under the action of air displaced from the pores, pollution, dust, including dangerous bacteria and the virus, rise up and spread inside an enclosed space).

- the constant need for the presence of service personnel at the entrance to buildings to maintain the rugs in a normal condition, while the risk of personnel infection with coronavirus infection and concomitant lung diseases increases (constant work in dusty conditions).

In the search process, no solutions were found using a bath with a disinfecting liquid agent for disinfecting the soles of shoes, and therefore the solution from DE 4441637 is used as a prototype, as it coincides in terms of the use of a tray with elements for cleaning the soles of shoes when a person passes this tray.

Known device (DE 4441637, A47L23 / 26, publ. 05/30/1996) for cleaning the sole of shoes, including a housing built into the floor of the room with a trough-shaped recess, a drive for rotation of cleaning elements placed in the housing recess, while the cleaning elements are made in the form of closed in a ring of V-belts having two solid drive shafts on the outer surface of the brush, drive pulleys fixed on the drive shafts, two driven shafts, driven pulleys freely rotating on the driven shafts. Every second V-belt rotates in the direction opposite to the splicing of adjacent belts. The belts are located next to each other to form a cleaning surface in which the belts rotate in a direction perpendicular to the direction of movement of the person. A bath with a replaceable and renewable cleaning agent is located under the body (a computer-controlled pumping system works), when the belts rotate, their lower branches pass through this bath and are cleaned of dirt.

This decision was made as a prototype for the declared objects.

The disadvantage of this solution in terms of disinfecting cleaning of the soles of shoes is that it is designed to clean the soles of a walking person's shoes from dirt and dust and possibly from wet contamination (for example, from snow or excess water after rain) and, in fact, does not disinfect the soles ... The presence of a bath with a renewable cleaning agent, including a disinfectant, allows you to clean and disinfect the belts themselves, which, after cleaning, when rotating, return to the level of the upper branches and form the cleaning surface of the shoe soles. Any disinfectant maintains its functionality either with a large amount, in which oxidative reactions have no visible effect, or under conditions of rapid application of this agent to the object. In the known solution, the belts in the lower branches are not washed, but are superficially wetted. Therefore, these belts reach the level of the upper branches in a state where the disinfectant loses its capacity due to oxidative reaction with air. It should be borne in mind that to ensure the normal and comfortable passage of a person on the surface of the rotating belts, their speed should be insignificant so as not to create an overturning moment. That is, the speed of rotation of the belts should be less than the speed of movement of a person on these belts. This determines the weak and ineffective operation of the known device in terms of disinfection of the soles of footwear of a walking person. The issue of disinfection by this known device is not solved in view of the fact that there are no conditions for wet processing of the soles with a disinfectant for a given time.

Another disadvantage of the known solution is that, when passing from the upper branches to the lower belts, a series of stationary brushes pass, which clean the dirt from the belts. Dirt falls to the bottom of the case. And only after that the lower branches of the belts pass through the bath, where they are cleaned with separate wetted brushes. Thus, the known solution is aimed solely at cleaning the soles of a walking person's shoes from dirt and belts from the same dirt. Dried dirt on the bottom of the case is a concentrator of pathogens and viruses, which leads to the opposite effect in the form of airborne dispersion of suspended particles, including the virus. Dust, including dangerous bacteria and viruses, rises and spreads inside the enclosed space. Suspended dust is also carried by belts from the area of the bottom of the case to the area of the upper branches of the belts.

The present invention is aimed at solving the problem of disinfecting the soles of shoes from infectious and parasitic diseases, as a component of nonspecific preventive measures to reduce microbial contamination.

"Prevention" is a set of measures that are aimed both at preventing the development of the disease and at stopping the spread of pathogenic microorganisms harmful to humans. And "non-specific prevention" refers to general measures that affect the effectiveness of the spread of a pathogenic agent.

The sole of the shoe is the main breeding ground for viruses, bacteria and fungi on shoes. At the same time, it is likely that droplets carried by a sick person through the air can settle on the upper part of the shoe, in its heel, on the laces, and so on. Typically, soles are made from rubber, PVC, plastic-lined leather, and other porous synthetic materials. They "catch" bacteria well. The recommendations of the World Health Organization provide for the treatment of all surfaces with alcohol solutions. But at the same time, leather or leatherette can be hopelessly damaged. In this regard, the practice has been developed of treating only the sole with alcohol antiseptics, without touching the top. To disinfect the soles of shoes, formulations with a high alcohol content or disinfectants with chlorine can be used. In any case, disinfection cleaning of the soles of shoes is only effective when the soles are washed or washed with a disinfectant, or when the sole is in a disinfectant. When using the wet method of processing the sole, there is no need to temporarily hold the object to be cleaned in liquid due to the fact that when wetting, a liquid film forms on the sole, which blocks oxidative reactions, without which microorganisms cannot develop.

The present invention is aimed at achieving a technical result, which consists in providing prompt and guaranteed high-quality disinfection of the shoe sole of a person entering or leaving the premises while avoiding his stopping in movement due to wet treatment of the sole with a disinfectant.

The specified technical result is achieved by the fact that the device for the treatment area of the soles of shoes for the system for the implementation of nonspecific prophylaxis of disinfection of the soles of shoes contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface along which people move in the bath cavity a hollow frame with hollow longitudinal and transverse elements is installed, communicated with the pump for pumping out the disinfectant solution and in the upper parts of which there are through holes for draining the excess of this liquid, nozzles for supplying a clean disinfectant solution into the bath cavity, which are communicated with the pump for supplying this liquid to the specified nozzles , and at least one optical sensor for monitoring the level of the disinfectant solution above the grill level.

At the same time, in this device, the support frame can be mounted on the floor of a building or room and equipped with ramps at the entrance to and exit from the grating, or mounted in a niche in the floor of a building or room, but without ramps.

The support frame is made with height-adjustable supports, and the support lattice is made with elements supporting it on the bathtub to prevent sagging under the weight of walking people.

Nozzles for supplying a clean disinfectant solution to the bath cavity can be mounted on hollow frame elements.

The specified technical result is also achieved by the fact that the system for the implementation of automatic nonspecific prophylaxis of disinfection of the soles of shoes contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface on which people move, a hollow frame is installed in the bath cavity with hollow longitudinal and transverse elements having through holes in the walls for draining the excess of this liquid from the cavity of this frame, which is communicated through the filtration unit with the pumping pump of the hydraulic unit, in which the supply pump is connected to the container for storing the disinfectant solution and through the check valve with pipes, communicated with nozzles placed in the bath cavity for supplying a clean disinfectant solution into the bath cavity, while the system contains at least one optical sensor for monitoring the level of the disinfectant solution above the grill level, communicated via a communication channel with the computerized control unit, made with the function of turning on the supply pump when the level of the disinfectant solution drops above the grate level to restore the thickness of the specified solution above the grate level.

In this system, the pump outlet is connected to the tank for storing the disinfectant solution, and the control unit is made on a processor basis and is connected to an optical sensor that detects the state of the disinfectant solution film above the grill level, and to the executive units for controlling the pumps for pumping out and supplying the disinfectant solution.

The specified technical result is also achieved by the fact that the method of non-specific prevention of disinfection of the soles of shoes consists in placing at the entrance or exit of a building or room of a building or an open area on the way for people to pass a lattice over which a layer of disinfectant solution is formed, placing at the surface level of this layer forming an optical sensor to measure the thickness of this layer of two fiber-optic radiation sources modulated in amplitude monochrome radiation at different wavelengths of the infrared spectrum and two radiation receivers with two inputs of fiber-optic lines of different diameters with the implementation of modulation of radiation sources with two different multiple frequencies, recorded as a reference parameter, the signals from the specified sensor, corresponding to the required thickness of the measured layer of the disinfectant solution, and carried out in the current time mode or at specified time intervals, receiving signals from the microprocessor optically th sensor at different radiation frequencies for each receiving aperture and form the signal ratios, which together determine the film thickness, and when the critical low level of the disinfectant solution layer thickness is reached, generate a control signal for the hydraulic system to turn on the pump for supplying fresh disinfectant liquid to this layer.

These features are essential and interconnected with the formation of a stable set of essential features sufficient to obtain the specified technical result.

The stated solution is illustrated by explanatory illustrative material, on which:

fig. 1 is a plan view (top) of a device for the implementation of non-specific prophylaxis for disinfection of shoe soles;

fig. 2 - the same as in FIG. 1 in block diagram form;

fig. 3 - the same as in FIG. 1, disassembled;

fig. 4 is a general view of the frame of the mechanism for taking and supplying a disinfectant;

Fig. 5 is a general view of the pallet / bath and its supporting frame on adjustable supports;

fig. 6 - shows a variant with tilting support grid;

fig. 7 - shows an embodiment with a tipping support grid and a lattice support frame with tubes, feeding fluid nozzles and sensors;

fig. 8 - optical block in the form of measuring systems emitter / receiver with different apertures.

A new design of a system for the implementation of nonspecific prophylaxis of shoe soles disinfection is proposed, based on the wet treatment of the soles of shoes entering and leaving a building or a room or an open area of people in the mode of maintaining their movement (that is, without stopping their movement) with constant monitoring of the level of the liquid film on processing area.

The main goal of introducing this domestic technology is to prevent the penetration and spread of any pathogens of infectious diseases in crowded places in public buildings.

Entering people pass through the disinfection work area, stepping on a support grid located in a 50 mm high pallet filled with a disinfector. At the same time, the thickness of the irreducible level of the liquid film of the disinfector above the grill is only 2 mm (controlled by an optical control method). After passing (2-3 steps) in this area, complete disinfection of the soles of shoes is performed. The spent disinfection solution can either be drained or regenerated.

Control of the hydraulic system, collection and processing of data from measuring instruments is carried out by a microprocessor and does not require the presence of personnel. At the same time, the chemical composition is automatically analyzed and the required concentration and level of the disinfector is maintained, the length of the working area is optimized to provide the required exposure for complete disinfection of the soles of people's shoes. The measuring instruments used a method for measuring the conductivity and electrochemical polarization of a solution. Any liquid disinfectant can be used in the system.

Thus, an automatic stationary engineering system for the implementation of preventive disinfection of the soles of people's shoes is a technological solution aimed at non-specific prophylaxis and reducing the risk of the spread of infectious diseases.

Such a system includes the following components: a treatment area, a hydraulic actuator that maintains the required level of disinfectant solution in the area for processing the soles of shoes, a pumping unit with an automatic system for supplying fluid to the actuator with preset parameters (pressure and flow), a presence control unit a sufficient amount of disinfectant liquid and information and signaling equipment.

In the general case, the device for the treatment area of the soles of shoes for the system for the implementation of nonspecific prophylaxis of disinfection of the soles of shoes contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface along which people move, a hollow frame is installed in the cavity of the bath with hollow longitudinal and transverse elements communicated with the pump for pumping out the disinfectant solution and in the upper parts of which there are through holes for draining the excess of this liquid, while nozzles are mounted on the elements of the said hollow frame for supplying a clean disinfecting solution into the bath cavity, which are communicated with the supply pump of this liquid to the indicated nozzles, and at least one optical sensor for monitoring the level of the disinfectant solution above the grate level.

At the same time, in this device, the support frame can be mounted on the floor of a building or room and equipped with ramps at the entrance to and exit from the grating, or mounted in a niche in the floor of a building or room, but without ramps. The support frame is made with height-adjustable supports, and the support lattice is made with elements supporting it on the bathtub to prevent sagging under the weight of walking people.

And the system for the implementation of nonspecific prophylaxis of disinfection of shoe soles, in the general case, contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which there is a support grid, which is a surface on which people move, in the cavity of the bath there is a hollow frame with hollow longitudinal and transverse elements having through holes in the walls for draining excess of this liquid from the cavity of this frame, which is communicated through the filtration unit with the pumping pump of the hydraulic unit, in which the supply pump is communicated with the container for storing the disinfectant solution and through the check valve with pipes communicated with the placed on a hollow frame with nozzles for supplying a clean disinfectant solution into the bath cavity, while the system contains at least one optical sensor for monitoring the level of the disinfectant solution above the grill level, communicated via a communication channel with a computerized control unit made with the function by turning on the supply pump when the level of the disinfectant solution drops above the grate level to restore the thickness of the specified solution above the grate level.

In this system, the pump outlet is connected to the tank for storing the disinfectant solution, and the control unit is made on a processor basis and is connected to an optical sensor that detects the state of the disinfectant solution film above the grill level, and to the executive units for controlling the pumps for pumping out and supplying the disinfectant solution.

Below is an example of a specific implementation of the claimed invention.

Processing area 1 is a horizontal flat platform, the area of which should provide for multiple contact with the sole of the shoe (calculated for several steps of a person walking on the platform). The surface of the area to be treated should be easy to rinse, not absorb liquid, and also not retain contamination. A collection system should be provided to remove excess fluid while maintaining the required fluid level.

In the processing area 1 (Fig. 1, 2), a receiving tank 2 of a non-capital type made of heat-resistant steel or composite materials is installed, with fastening elements for other auxiliary elements. For unimpeded access to the treatment zone at the entrance / exit from the treatment zone 1, ramps 3 are installed. In the design of a capital-type receiving tank (when a niche is installed in the floor), ramps are not required. The receiving bath 2 is in the form of a tray or trough, that is, it has a bottom and side walls extending from it, forming a cavity in which the disinfecting liquid is located. This bath is placed on a support frame 4, which is made with adjustable supports, which make it possible to align the horizontal position of the bath (Fig. 5) relative to the installation surface. On top of the support frame 4, a support grid 5 is installed for the disinfecting passage (Fig. 3), which is made with support elements to prevent the structure from deflecting (these support elements are not shown illustratively).

Treatment area 1 is equipped with a hydraulic system for maintaining the required amount of disinfectant liquid in the receiving bath with a grid placed on it to form and maintain a liquid layer above the support grid at a given level 5. When passing through the treatment area (more precisely, along the support grid), the sole of the shoe touches a thin layer disinfecting liquid, the thickness of which is strictly regulated due to the level maintenance system, which includes automatic supply, if necessary, upon a signal from special sensors for measuring the thickness of the disinfecting liquid film.

The unit for supplying and removing the disinfectant liquid is installed inside the receiving bath (capital or non-capital type) and is a hollow frame 6 (Fig. 4). The frame is made with outlet openings 7, which are made in the upper part of the frame of the frame 6 and through which the disinfectant liquid is removed along the hydraulic circuit for the intake of excess liquid and dirty liquid, in which the pumping pump 8 is built (Fig. 2). When pumping out, the liquid passes through the filtration unit and is directed into the container 9 for storing the disinfectant liquid, with which the pump 10 for supplying this liquid to the bath cavity is communicated (Figs. 1 and 2). The outlet of this pump 10 through the check valve 11 communicates either directly with the supply pipes 12 located in the cavity of the bath for supplying a clean disinfectant to the bath, or with a flow distributor 13, which is in communication with the said tubes 12 (Fig. 4). Both options for communication with inlet pipes are equivalent. At the end of each tube 12, placed in the bath cavity in the area of the hollow frame 6 under the grid 5, a distributor head 13 is mounted (Figs. 1, 2 and 4), which performs the function of a nozzle and is made in the form of a nozzle (Fig. 1).

Distributing heads 13 at the end of the supply pipes 12 are installed in the center of the bath (spaced relative to each other over the area of the bath). Structurally, each head is made of a housing 14 with a cavity 15 inside, communicated with an opening in the wall of the housing, in which the unit for connecting the supply tube 12 is mounted. In the center of the cavity, a mounting platform is mounted for placing a conical or tapered cover 16, with a smaller base resting against this mounting platform. The cover is secured in the body with a bolt 17, passed through the cover and screwed into the support platform (Fig. 1). By adjusting the tightening of the bolt 17, the gap between the body and the tapered surface of the lid is provided, through which the disinfectant liquid is poured into the cavity of the bath. When the disinfectant liquid is supplied to the dispensing heads, the liquid level rises, and excess liquid begins to flow into the outlet openings 7 on the hollow frame 6, entering the hollow part and, as a result, into the contaminated liquid intake circuit with the pumping pump 8.

The pumping unit, built on the basis of the liquid supply pump 10, is equipped with an automation unit 18 (Figs. 1 and 2) for supplying fluid to the actuator with predetermined parameters (pressure and flow rate). This pumping unit is in communication with the container 9 for storing the disinfectant liquid with a membrane-type pump located inside or on the side of it to prevent the disinfecting liquid from stratifying when it is fed into the actuator. The automation unit 18 is used to control the equipment and supply fluid to the executive processing lines. The capacity 9 for storing the disinfectant liquid is determined by needs, depending on the permeability of the treatment area, and can range from 300 to 1800 liters.

To collect sedimentary contaminants, the bottom of the receiving bath is made with a slope to one or both sides. As an option, a mechanism for moving along the "chute" zone of a screw or belt type (not shown in the figures) can be used. The sediment at the bottom of the bath can also be removed mechanically, while the cavity of the bath can be accessed by lifting the support grid, which can be hinged to the bath on one side and secured with screw retainers on the other side (Fig. 6).

An embodiment of the device is possible, in which, to remove sediment at the bottom of the bath mechanically, access to the bath cavity can be carried out by lifting the support grid and the hollow frame with feeding nozzles and sensors. For the latter case, the support grid and the hollow frame can be pivotally connected to the bath along the edge of the latter so that these units can be lifted in different directions, like sash, (Fig. 7).

The claimed system provides control over the availability of the required amount of disinfectant liquid in the bath and above the grate level. The main element of the automatic operation of the system is a module for monitoring the presence of a disinfectant at the treatment area with activation of the distribution of a disinfectant in the event of a minimum liquid level on the surface.

The principle of maintaining the required level of application of the disinfectant is based on constant measurement of the thickness of the water (liquid) film in the treatment area (above the grate level) using a specialized optical sensor 19 (Fig. 3), as well as determining the concentration of the disinfectant in the solution on the coating (in winter during the period, the concentration can drop dramatically along with the snow brought outside). If an insufficient amount of disinfectant is detected, the system automatically switches to the mode of supply of disinfectant liquid to maintain the level required for treatment.

In the general case, for the specified task of measuring the thickness of the water (liquid) film in the processing area (above the grating level), a specialized optical sensor 19 is used, which contains a housing placed in the liquid layer with a working platform located on the surface of this layer. The housing contains at least one optical unit connected to the microprocessor and sensors and brought out to the working platform of the housing for measuring the thickness of the water film. This optical unit (Fig. 8) can have various design variations in terms of the use of electronic components and their arrangement in the housing. The main thing is that it contains a first transmitter 20 of radiation in the range, for example, 950-960 nm, a nearby second transmitter 21 of radiation in the range, for example, 860-870 nm, and two receiving channels 22 and 23, respectively for two reflected from liquid-air boundaries of radiation, as well as a built-in microprocessor. In this case, the elements themselves (pos. 20-23) can be located in the housing, and only the receiving parts of the receivers and the apertures of the emitters are brought out on the surface of the air-liquid medium boundary. A feature of the measuring unit is that each radiation receiver has two inputs of fiber-optic lines of different diameters (apertures) 0.5 and 1.0 mm, connected to the radiation receivers. As a result, we get 4 values of the output signal for one measurement cycle:

1. Voltage at the receiver with a 1 mm fiber from the IR emitter with a wavelength of 870 nm,

2. Voltage at the receiver with a 0.5 mm fiber from the IR emitter with a wavelength of 870 nm,

3. Voltage at the receiver with a 1 mm fiber from the IR emitter with a wavelength of 950 nm,

4. Voltage across the receiver with a 0.5 mm fiber from the IR emitter with a wavelength of 950 nm.

Determination of the thickness of optically transparent or turbid media with the use of the described optical sensor consists in the fact that at the level of the surface on which the layer of the optically transparent and / or turbid medium is located, two fiber-optic sources of radiation of amplitude-modulated monochrome radiation at different wavelengths of infrared spectrum and two radiation receivers with two inputs of fiber-optic lines of different diameters. Modulation of radiation sources is carried out by two different multiple frequencies. The signal received by the receivers is formed by synchronous detection, then from the obtained signal values at different radiation frequencies for each receiving aperture, signal ratios are formed, which together determine the film thickness (this method is described in detail in RU 2734576). The control is based on the signals of the optical water film thickness sensor described above. When a critical low level of water film thickness is reached, a signal is generated that can control the hydraulic system for supplying fresh disinfectant fluid. The optical sensor is made with a built-in microprocessor for the possibility of connecting a communication cable to it for remote data transmission via the RS485 interface to a computerized control system.

This sensor is used to determine the thickness of the layer and the dispersion of this thickness, calculated for different pairs of wavelengths and diameters of the apertures.

The sensor is small-sized, containing a housing of predominantly parallelepipedal or cylindrical shape or in the shape of a cone-shaped truncated pyramid.

In fact, the invention implements a method for non-specific prophylaxis of shoe soles disinfection, which consists in placing a lattice at the entrance or exit from a building or a building or an open area on the way for people to pass, over which a layer of disinfectant solution is formed. Also, at the surface level of this layer, an optical sensor is placed to measure the thickness of this layer, which consists of two fiber-optic sources of radiation of amplitude-modulated monochrome radiation at different wavelengths of the infrared spectrum and two radiation receivers with two inputs of fiber-optic lines of different diameters with the implementation modulation of radiation sources with two different non-multiple frequencies. At the same time, the signals from the specified sensor are recorded as a reference parameter, corresponding to the required thickness of the measured layer of the disinfectant solution, and signals are received from the microprocessor of the optical sensor at different radiation frequencies for each receiving aperture in the current time mode or at specified intervals, and signal ratios are formed, the aggregate of which determines the thickness of the film. And when a critically low level of the disinfectant layer thickness is reached, a control signal is generated for the hydraulic system to turn on the pump for supplying fresh disinfectant liquid to this layer.

In the case of more complex technological operations of a multistage nature, it is possible to install several sections of disinfection treatment in a cascade way (one after another along the corridor), which may contain various disinfectants of a complex type. In the case of application in different climatic conditions, heating or conditioning (liquid cooling) of the working solution is possible. In this case, cooling is possible using radiators with Peltier elements.

The heating elements are a heat exchanger block with tubes around which disinfectant liquid flows when it is fed into the bath. If necessary, the liquid is heated through the tubes of the heat exchanger by means of electric heating elements supplied through these tubes with a preheated working fluid. If cooling is required, the working fluid is cooled using heat exchangers with Peltier elements.

Alternatively, it is possible to supply the disinfectant solution from the bottom of the receiving bath in the form of a foamed composition, for example, by supplying air to this solution. The piping, which connects directly to the distribution nozzle, is supplied with a separate pressurized air tube. When air is supplied in the tube, a mixture of liquid with gas occurs and a foamed solution is supplied to the surface.

The system and method for disinfection of shoe soles at the entrance to public buildings / clean rooms or exiting buildings / premises or an open area with a large crowd of people is aimed at reducing the risk of spreading infectious agents in confined spaces by reducing microbial contamination. The invention is based on the passage by pedestrians of a special working platform for processing in the form of a depression with an irreducible level of the working disinfectant solution, supported by a hydraulic system automatically controlled and controlling the solution level by means of optical methods for measuring the thickness of the water film, as well as the composition and concentration of the disinfectant solution by electrochemical measurement methods.

Claims (10)

1. Arrangement of a treatment area for shoe soles for a system for the implementation of nonspecific prophylaxis for disinfection of shoe soles, characterized in that it contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface on which people move in the bath cavity a hollow frame is installed with hollow longitudinal and transverse elements communicated with the pump for pumping out the disinfectant solution and in the upper parts of which there are through holes for draining the excess of this liquid, nozzles for supplying a clean disinfectant solution into the bath cavity, which are communicated with the pump for supplying this liquid to the specified nozzles , and at least one optical sensor for monitoring the level of the disinfectant solution above the grill level. 2. The device according to claim. 1, characterized in that the support frame is mounted on the floor of the building or room and is equipped with ramps at the area of entry to and exit from the grating. 3. The device according to claim. 1, characterized in that the support frame is mounted in a niche in the floor of the building or room. 4. The device according to claim. 1, characterized in that the support frame is made with height-adjustable supports. 5. The device according to claim. 1, characterized in that the support lattice is made with elements of its support on the bathtub to prevent sagging under the weight of walking people. 6. The device according to claim 1, characterized in that the nozzles for supplying a clean disinfectant solution into the bath cavity are mounted on the elements of the hollow frame. 7. A system for the implementation of automatic nonspecific prophylaxis of shoe soles disinfection, characterized by the fact that it contains a tray-type bath placed on a support frame and filled with a disinfectant solution, on top of which a support grid is placed, which is a surface on which people move, a hollow frame with hollow longitudinal and transverse elements having through holes in the walls for draining excess of this liquid from the cavity of this frame, which is communicated through the filtration unit with the pumping pump of the hydraulic unit, in which the supply pump is communicated with the container for storing the disinfectant solution and through the check valve with pipes communicated with nozzles placed in the bath cavity for supplying a clean disinfectant solution into the bath cavity, while the system contains at least one optical sensor for monitoring the level of the disinfectant solution above the grill level, communicated via a communication channel with a computerized unit control performed with the function of turning on the supply pump when the level of the disinfectant solution drops above the grate level to restore the thickness of the specified solution above the grate level. 8. The system according to claim 7, characterized in that the outlet of the pumping pump is in communication with the container for storing the disinfectant solution. 9. The system according to claim. 7, characterized in that the control unit is made on a processor basis and is connected with an optical sensor, which is a detector of the state of the disinfectant solution film above the grill level, and with executive units for controlling the pumps for pumping out and supplying the disinfectant solution. 10. A method of non-specific prevention of disinfection of shoe soles, which consists in placing at the entrance or exit of a building or room of a building or an open area on the way for people to pass a lattice over which a layer of disinfectant solution is formed, placing at the surface level of this layer forming an optical sensor for measuring the thickness of this layer two fiber-optic radiation sources of amplitude-modulated monochrome radiation at different wavelengths of the infrared spectrum and two radiation receivers with two inputs of fiber-optic lines of different diameters with the implementation of modulation of radiation sources with two different non-multiple frequencies, the signals from the specified sensor are recorded as a reference parameter, corresponding to the required thickness of the measured layer of the disinfectant solution, and carry out in the current time mode or at specified time intervals, receiving signals from the microprocessor of the optical sensor at different radiation frequencies for each pr aperture and form the signal ratios, which together determine the film thickness, and when the critical low level of the disinfectant solution layer thickness is reached, a control signal is generated for the hydraulic system to turn on the pump for supplying fresh disinfectant liquid to this layer.

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