RU2747519C1 - Underground garbage storage system - Google Patents

Abstract

FIELD: garbage treatment.SUBSTANCE: invention relates to an underground system for the collection and temporary storage of garbage (waste). The system has lifts for garbage containers. The invention also relates to a method for its disinfection by treatment with ozone or ozone and ultraviolet radiation. The underground garbage storage system contains a caisson in which a cage for garbage containers is installed which has the ability to move vertically by the cage movement mechanism and is formed by a force set connecting the horizontal lower platform of the cage with its upper platform which overlaps the inner part of the caisson when the cage is lowered to the extreme lower position. At least one hole is made in the upper platform above which a garbage bin is fixed. The system is equipped with at least one disinfectant that generates ozone for the disinfection and deodorization of garbage as well as for the disinfection of all internal surfaces of the caisson and the equipment located in it as well as the air inside the caisson to prevent the reproduction of harmful microorganisms. The disinfectant is installed in the casing on the upper platform with the possibility of vertical movement into the interior of the caisson and containers. In addition, the system can be equipped with forced exhaust ventilation equipped with ozone-free germicidal ultraviolet lamps installed at its entrance.EFFECT: invention makes the collection and temporary storage of garbage more effective.19 cl, 6 dwg

Description

The invention relates to an underground system for the collection and temporary storage of garbage (waste), having lifts for garbage containers, as well as to a method for its disinfection by means of ozonation or ozonation with ultraviolet radiation.

An underground system for garbage collection is known (RU 2492127, 09/10/2013), containing independent modules for various types of garbage collected, consisting in its underground zone of a bunker and a container for removing garbage by a crane, and on the surface - from a post with an entrance bin used by certain users with a hinged lid. The system contains means for opening and closing the lid, safety devices with a movable component leaning against the bunker wall when the container is inside the bunker and made with the ability to automatically unfold when the container is removed to a horizontal position with overlapping the bunker opening. The system also contains a means for opening and closing the entrance bin, a coupling device connected to the crane boom and providing the ability to automatically lift and transfer the container to the emptying zone. In this case, the coupling device contains a horizontal beam and two vertical consoles made with the possibility of vertical movement by hydraulic cylinders. Each cantilever contains an external component having a grip at the end for engagement, means for automatically connecting the container to the crane, the stationary coupling elements of which are attached to the container body on each of its lateral sides and have cutouts at the upper ends for engaging with the outer component of the cantilever.

A device for sterilizing waste containers installed inside a vertical container is known (US 6365113, 02/04/2002). The sterilization device contains a source of ultraviolet radiation, mainly in the wavelength range from 200 to 300 nm to obtain a bactericidal and sterilizing effect due to direct irradiation. In addition, the sterilization device can use ultraviolet radiation with a wavelength below 200 nm, which contributes to the formation of ozone, and ozone, in turn, has a significant bactericidal and sterilizing effect and, since ozone is a gas, it is able to penetrate into the crevices of garbage containers where ultraviolet radiation cannot reach, especially when several waste containers are sterilized at the same time. The sterilization device contains a top cover hinged to the waste container. The UV lamps are attached to the top cover, and the device may contain more than two lamps, both mounted in the top cover and located at the bottom of the container. The lamps can be of any type, including U-shaped lamps, ring lamps, conventional UV lamps, and any other lamp that emits ultraviolet radiation necessary for sterilization. The source of ultraviolet radiation is installed inside the container body in such a way that ultraviolet radiation falls directly on the items to be sterilized and is reflected from them. The interior of the container can also reflect ultraviolet radiation in different directions to both directly and indirectly reach all parts of the waste containers to be sterilized.

Known garbage collection system (CN 207390164, 12.10.2006), containing a left container and a right container for garbage, installed inside a common housing. The system is designed to prevent the scattering of garbage, as well as to disinfect the garbage, which avoids the growth of microorganisms, at the same time, the system ensures the convenience of removing garbage. The system contains a housing, inside of which there are two cavities, in which the left container and the right container are installed, having the ability to roll out, respectively, to the left side and to the right side. The system includes a solar panel as well as UV lamps located on the left and right side.

The closest analogue is an underground garbage collection device equipped with lifting devices (EP 0858960 A1, 19.08.1998). The device contains a caisson located underground, in which a lifting cage is installed to accommodate a garbage container equipped with wheels, while an urn is fixed in the upper part of the lifting cage. In the lower part of the caisson, there is a lifting mechanism that does not have its own engine and consists of a base, combined with at least one vertical post, which provides movement and maintenance of the supporting horizontal structure on which the stand is installed. The horizontal structure is connected by a belt drive with a gearbox. The gearbox is equipped with a so-called slot-type clutch and power take-off device, which is designed to interact with the tip of an external motor, and the tip is made like a screwdriver head and is driven by an external motor to be moved by the operator.

Known analogs, including the closest analogue, are not intended for sterilization of devices for underground storage of garbage and for its sterilization.

During underground storage of garbage, various small-sized organic and inorganic wastes (municipal solid waste, municipal solid waste), kitchen and food residues, paper, plastic bags, plastic packaging, enter the container located under the trash can, as described, for example, in EP 0858960, glass, etc. Old clothes, shoes, packaging materials are also thrown into the garbage containers. Complex chemical processes occur in the accumulating waste contained in garbage containers, as a result of which methane and other associated gases, including those produced by microorganisms, are formed. This creates an unpleasant odor area around the waste collection facilities. In addition, the underground part of such devices can become a habitat for rodents with access to waste, including food, located in the interior of garbage containers.

The technical problem solved by the claimed invention is the creation of a technical solution that provides a high degree of disinfection, a high degree of deodorization and the absence of unpleasant odors from the underground garbage storage device and from the garbage itself, in compliance with the safety of the disinfection process.

Solid municipal waste or MSW (Article 1 of the Law on Production and Consumption Waste) is waste generated in residential premises in the process of consumption by individuals, as well as goods that have lost their consumer properties in the process of their use by individuals in residential premises in order to satisfy personal and household needs. Solid municipal waste - MSW also includes waste generated in the course of the activities of legal entities, individual entrepreneurs and similar in composition to waste generated in residential premises during consumption by individuals, as well as garbage when cleaning the territory of settlements (street estimates, garbage after staying in public areas, beaches, etc.).

Solid household waste or MSW (clause 3.3 of GOST R 53691-2009. "National standard of the Russian Federation. Resource saving. Waste management. Waste passport of I-IV hazard class. Basic requirements") means consumer waste generated by the population, including including when cooking, cleaning and repairing living quarters, maintaining adjacent territories and common areas, keeping pets and birds in residential premises, as well as outdated household items that have become unusable.

As follows from the above definitions, MSW and MSW are one type of waste. The claimed invention relates to the safe collection and underground storage of the aforementioned waste (garbage) with treatment by means of ozone or ozone and ultraviolet radiation while ensuring the simplicity and ease of maintenance of the system.

The technical problem of decontaminating the interior of the underground garbage storage system (hereinafter referred to as the SPHM) and the garbage itself, as well as eliminating the unpleasant odor emanating from the location of the SPHM and coming directly from the garbage, is solved by the proposed design of the SPHM and the proposed method of processing the internal parts of the SPHM caisson, garbage containers and garbage with ozone. It is known that ozone is the most environmentally friendly oxidant, fungicide, deodorizer and disinfectant. The use of ozone does not lead to environmental pollution by by-products, since due to the fact that the ozone molecule is not stable, the unused ozone decomposes and turns into diatomic oxygen.

Like the closest analogue, the underground garbage storage system (UGS) contains a caisson, in which a cage for garbage containers is installed, which can be vertically displaced by the cage movement mechanism and is formed by a force set connecting the horizontal lower platform of the cage with its upper platform overlapping the inner part of the caisson , when the cage is lowered to the extreme lower position, while at least one hole is made in the upper platform, above which the urn is fixed.

The specified technical problem is solved due to the fact that the SPHM is equipped with at least one disinfection means that generates ozone, installed in the casing on the upper platform with the possibility of vertical movement, while the disinfection means that generate ozone is made in the form of an ozonizer or UV lamp, generating ozone, installed in a metal mesh casing. A disinfectant in the form of an ozonizer or a UV lamp generating ozone is installed on an actuator fixed in the casing and which removes the disinfectant from the casing and lowering it into the garbage container and lifting it from the garbage container back into the casing. In addition, the system is equipped with forced exhaust ventilation equipped with germicidal ozone-free ultraviolet lamps installed at its entrance.

The mechanism for moving the stand is made in the form of a hydraulic lift with hydraulic cylinders powered by a hydraulic station (hydraulic drive) located in a metal body outside the caisson.

The casing, in which the disinfectant generating ozone is installed, is attached to the urn and is open on the inside for lowering and lifting the disinfecting agent and has slots for air intake from the outside, located above the upper platform.

In addition, in a particular case of implementation, the system can be equipped with forced exhaust ventilation, equipped with bactericidal ozone-free ultraviolet lamps installed at its entrance. Forced exhaust ventilation is equipped with a built-in duct fan and can also be equipped with an anti-ozone filter. Ozone-free germicidal UV lamps, located at the entrance to the forced exhaust ventilation, are installed at the rear wall of the caisson in its lower part near the horizontal lower platform, where the entrance to the forced exhaust ventilation is also located. The entrance to the forced exhaust ventilation (inlet channel) is equipped with an electrically driven damper that closes the entrance to the forced exhaust ventilation when the SPHM is inoperative. The number of forced draft ventilation channels ranges from one to four.

The cage is made with at least one opening between vertical drains, forming a power set, and each garbage container is equipped with wheels for moving it along the horizontal lower platform with the possibility of rolling out through the opening to the ground surface. The number of waste bins can be from one to eight.

The trash can, installed on the upper platform above the hole in it, is equipped with an opening / closing means, namely, a lid with a lock, while a gap is formed between the lid and the urn to allow air from the environment to flow into the caisson.

An exhaust ventilation box is located along the perimeter of the upper platform, which draws air from the water drain tray and the inner space of the cage.

SPKhM is equipped with a mechanism for tearing bags or packages located under the urn, while the said mechanism is made with toothed blades installed with the possibility of reciprocating movement, and the drive of the mechanism is made in the form of an electromechanical actuator containing an electric motor-reducer and a toothed rack.

In addition, the SPHM is equipped with a gate located above the bag or bag tearing mechanism, while the gate is movable from a position overlapping the hole above which the urn or urn 8 is installed to the retracted position when the said hole is completely open.

Disinfection of the interior of the SPHM, which contains MSW (MSW), the interior of containers, other internal surfaces of the SPHM (inner walls of the caisson, outer walls of garbage containers, equipment of the SPHM), as well as air is carried out using ozonizers or UV lamps generating ozone.

The ozonizer absorbs oxygen from the air and delivers a strong electrical discharge to it. This electrical discharge allows the oxygen in the air to be rearranged and form ozone gas - Oz. The ozone then leaves the device in the trash can. On contact with debris, ozone, as a strong oxidant, reacts with the surface of debris particles, attaches to the pollutant molecules and destroys their structure.

The ozonizer consists of the following parts:

- generator of electrical discharges;

- high voltage source;

- a fan for air intake and ozone mixture supply to the garbage container and the caisson space.

Ozone formed from oxygen in the air under the influence of ozonizers, where the method of producing ozone is electrosynthesis, which uses the dissociation of oxygen molecules under the influence of the energy of an electric discharge in a dielectric gap (barrier), or radiation from ozone-forming ultraviolet lamps (UV lamps), disinfects surfaces and provides deodorizing effect.

Ozone-free germicidal UV lamps with ultraviolet radiation wavelengths from 205 nm to 315 nm, peak 265 nm (UV). These UV lamps also serve to decontaminate the air entering the exhaust ventilation.

The treatment of garbage in dumpsters, as noted above, is carried out by the intake of ozone from ozonizers or UV lamps that generate ozone. Uniform processing of garbage as it enters the garbage container is ensured by a mechanism for tearing bags or packages, i.e. a device that breaks and / or shreds bags (packages).

A gate closing the lower opening of the urn in a position overlapping the lower opening of the urn prevents ozone from entering from the space of the caisson into the space of the urn. The gate opens a hole under the trash can when bags or bags with garbage from the trash can fall onto the shutter, while the command to turn on the gear motor located under the corresponding trash can comes from the sensor with a photocell located above the shutter, a signal from the sensor turns on the gear motor, moving a rack with toothed blades attached thereto, i. e. the mechanism of tearing bags or bags with garbage is triggered.

The technical result from the use of the invention is the disinfection and deodorization of both garbage - solid household waste, solid municipal waste (MSW or MSW) and the disinfection of all internal surfaces of the caisson and the equipment located in it, as well as the air inside the caisson, inside and around garbage containers, preventing reproduction of harmful microorganisms (microbes, fungi, including mold, etc.). Disinfection of the inside of the SPHM, its elements and equipment, as well as the decontamination of MSW or MSW directly in garbage containers and the reduction or almost complete elimination of an unpleasant odor around the SPHM, including the smell emanating from garbage when loading it into garbage trucks, is carried out by using ozonizers or UV lamps that generate ozone. At the same time, the sanitary treatment of the inner surface of the caisson, the inner (without garbage and with garbage) and the outer surfaces of garbage containers is simplified, and garbage that gets into garbage containers is disinfected by creating conditions that prevent the reproduction of microorganisms (ozone generation), and an unpleasant odor is also eliminated , coming from the bins, from the caisson, the air around the bins and the caisson is disinfected, the unpleasant odor from garbage is eliminated, which can crumble when reloading into garbage trucks. Disinfection of garbage as it enters the garbage container allows to increase the period of temporary storage of MSW and MSW in the SPHM and allows designers to justify the reduction of the minimum distance established by SanPiN 42-128-4690-88 from the installation site of the SPHM to the walls of buildings. The claimed design, due to the instability of the ozone molecule, avoids the release of ozone into the environment. Additionally, you can use forced ventilation with UV ozone-free bactericidal lamps that destroy the ozone molecule, converting ozone (O ₃ ) into diatomic oxygen. In forced ventilation, along with or without the mentioned ozone-free UV lamps, an anti-ozone filter can be used.

Such a combined technology, without harming the environment (without the use of chemicals), provides dynamic, permanent, complete disinfection and elimination of unpleasant odors around the SPHM and when opening trash bins, as well as when transferring waste to garbage trucks. In addition, the declared SPHM provides disinfection of the air that comes out of the caisson. An additional result is that in summer it will be possible to temporarily store waste (MSW or MSW) treated with ozone and ultraviolet radiation for three days instead of one day, i.e. as it was allowed only in the cold season.

The invention is illustrated by drawings, which show:

FIG. 1 is a diagram of the location of the caisson and the cage with waste containers, the cage is lowered; the plan of the upper platform of the cage is also shown.

FIG. 1A - unit A from the layout of the caisson and stand.

FIG. 2 - section B-B from Fig. 2. The cage is lowered.

FIG. 3 - section b-b from fig. 2. The cage is raised.

FIG. 4 is a diagram of exhaust ventilation when installing a gate under the trash cans.

FIG. 5 - a simplified diagram of exhaust ventilation without installing a gate under the trash cans.

FIG. 6 - ozonizer.

In the drawings, the numbers indicate:

1 - Caisson.

2 - Garbage containers for municipal solid waste (MSW) and municipal solid waste (MSW).

3 - Cage lifting mechanism.

4 - Cage.

5 - Upper platform of the stand.

6 - Air inflow through the gap between the lid and the urn.

7 - Forced exhaust ventilation.

8 - Urn.

9 - Gate located under the urn with the actuator.

10 - Ozonizers (ozone generators).

11 - Ultraviolet ozone-free bactericidal lamps designed for the destruction of ozone, the conversion of ozone to oxygen (UV).

12 - A tray along the perimeter of the upper platform of the cage, intended for water drainage from the platform.

13 - The mechanism of tearing bags (packages), consisting of three serrated knives, driven by an actuator of the tearing mechanism.

14 - Exhaust ventilation box, located along the perimeter of the upper platform of the cage for air intake with ozone, which can penetrate through the gap between the caisson and the upper platform of the cage.

15 - Built-in duct exhaust ventilation fan with anti-ozone filter.

16 - Exhaust ventilation box located along the perimeter of the urn.

17 - Ozone stream leaving the ozonizer into the waste container.

18 - A stream of clean air leaving the exhaust ventilation after ozone decontamination by UV lamps (recirculators) and / or anti-ozone filters.

19 - Actuator for lowering ozonizers 10 into a waste container.

20 - A casing into which the ozonator 10 is mounted, as well as an actuator 19, which raises and lowers the ozonizer 10.

21 - Sensors with photocells giving a signal to trigger the bag (s) tearing mechanism.

22 - Housing for the hydroelectric station.

23 - Back (or front) wall of the caisson.

24 - Side wall of the caisson.

25 - Holes in urns. Holes connect the space of the trash cans and the exhaust ventilation box.

26 - Inlet channel of forced exhaust ventilation 7.

27 - Electric damper.

28 - Tee.

29 - Exhaust ventilation during operation without a gate.

30 - Fungus.

31 - Hole in the upper platform of the cage - the location of the lower part of the urn.

32 - Air intake located near the bottom of the bins.

33 - Ozonizer electrode.

34 - Dielectric barrier.

35 - The second electrode of the ozonizer.

36 - Ozonizer fan.

37 - Discharge gap in the form of an air channel.

38 - Hydraulic cylinder.

39 - Vertical guide post.

The underground garbage storage system designed for the collection of solid municipal waste - MSW (solid domestic waste - MSW), contains an underground part - a caisson 1, in which a cage 4 is installed with the possibility of vertical movement along vertical guide posts 39, and a ground part - 8 bins with lids and a control panel housed in the control rack. The control stand can, in particular, be installed on the cover of the housing of the hydraulic station 22.

The cage 4 for placing one or more garbage containers 2 is made with a horizontal lower platform, which is the floor, and the upper platform 5, tightly overlapping the inner part of the caisson 1 when the cage 4 is lowered to the extreme lower position. The power set of the stand 4 is made in the form of vertical posts, between which at least one opening is formed, through which waste containers 2 are rolled out of the cage. On the horizontal bottom platform of stand 4, i.e. on its floor, at least one garbage container 2 with wheels is installed to move it along the horizontal lower platform of cage 4 and roll it out through the opening in the side side of cage 4 to the surface outside the cage 4, to the ground surface to ensure the possibility of unloading waste from the garbage container 2 for transportation to the disposal site using conventional known means (garbage trucks, etc.) The number of garbage containers 2 in preferred embodiments of the invention can be from one to eight.

To receive garbage, an opening 31 is made in the upper platform 5, over which at least one urn 8 is fixed, equipped with an opening / closing means, namely, a lid with a lock. Between the lid and the urn 8, a gap is provided through which air flows (shown by arrow 6) inside the caisson 1.

An exhaust ventilation box 14 is located along the perimeter of the upper platform, which takes air from the chute 12 for the drainage of water coming from the outside of the SPHM (precipitation) and from the inner space of the stand.

The outlet part of the forced exhaust ventilation 7 with a built-in duct fan 15, which can be equipped with an anti-ozone filter, is passed through the upper platform 5. The outlet of the forced exhaust ventilation 7 is protected by a fungus 30. In addition, the forced exhaust ventilation 7 is equipped with ozone-free UV germicidal lamps 11 installed in front of the inlet to the duct fan 15 and designed for ozone destruction, i.e. conversion of ozone to diatomic oxygen. A feature of an ozone-free bactericidal lamp is its bulb, for the manufacture of which special glass is used, including with an additional titanium coating, which filters out ozone harmful to humans, generating radiation that destroys ozone molecules. The flow of clean air leaving forced exhaust ventilation 7 is shown by arrow 18.

The movement mechanism 3 of the stand 4 is a hydraulic lift with hydraulic cylinders 38, which operates from a hydraulic station (hydraulic drive) located in a metal body 22 outside the caisson 1. In the hydraulic cylinders 38, which raise / lower the stand 4, oil from the hydraulic station is supplied through high-pressure hoses ... The lifting mechanism 3 of stand 4 is controlled through the control panel located in the control stand and located near the SPHM, on the housing cover for the hydraulic station 22. To transfer garbage from garbage containers 2 to a garbage truck, the mechanism for moving garbage 3 of stand 4 lifts the cage with garbage containers 2 so, so that the lower platform (floor) of the cage is at ground level, which allows you to roll out garbage containers 2 from cage 4 for the subsequent transfer of garbage from containers 2 to a garbage truck.

Disinfection of the interior of the SPHM, which contains MSW (MSW), as well as the interior of garbage containers 2, other internal surfaces of the SPHM, including vertical guide racks 39, inner surfaces of the caisson: rear and front walls 23, side walls 24, outer walls of garbage containers 2, equipment of SPHM - hydraulic cylinders 38, etc., as well as air is produced by ozone generated by at least one disinfectant that generates ozone. Ozone generators 10 or ozone generating UV lamps are used as ozone generating means.

Ozonizer 10 uses oxygen in the air and exposes it to a strong electrical discharge. This electrical discharge allows the oxygen in the air to be rearranged and form ozone gas (O ₃ ). Ozone is formed as a result of the dissociation of an oxygen molecule as a result of the action of the energy of electrons moving between electrodes 33 and 35 through the discharge gap 37 in the form of an air channel.

Ozonizers 10 are placed in the casing 20 near the ballot boxes 8 and the holes in the upper platform, behind the exhaust ventilation box 14, located around the ballot boxes. The casing 20 is open on the inner side for lowering and raising the disinfection means and is made with openings for air intake from the outside, located above the upper platform. Ozonizers 10 are installed on actuators 19, which remove the ozonizers 10 from the casing 20 and lower them into the garbage containers 2 and lift them from the garbage containers 2 back into the casing 20.

Instead of the ozonizers 10, they can be replaced in the housings 20 by UV lamps of an open type that generate ozone. The ozone generating UV lamps are installed in a metal mesh casing that protects against mechanical damage, and are similarly connected to the actuators 19, which have the ability to lower the ozone generating UV lamps into waste containers 2 and lift them back into the casing 20.

Ozonizer 10 consists of the following parts:

- a generator of electrical discharges with electrodes 33, 35, a dielectric barrier 34 and a discharge gap 37 in the form of an air channel.

- high voltage source;

- the fan 36 of the ozonizer, which draws air into the ozonizer 10 and, after processing the oxygen of the air with an electric discharge, supplies ozone to the inner volume of the garbage containers 2 and the caisson 1. The ozone flow leaving the ozonizer 10 into the garbage container 2 is shown by arrows 17.

In UV lamps that generate ozone, under the influence of short-wave UV irradiation, an oxygen molecule dissociates into 2 atoms, and then ozone is formed by the fusion of an atom and a whole oxygen molecule. Ozone is supplied to the inner part of the garbage containers 2 and to the inner volume of the caisson 1 in the same way as from the ozonizers 10.

Ozone formed from oxygen in the air under the influence of ozonizers 10, where the method of producing ozone is electrosynthesis, which uses the dissociation of oxygen molecules under the influence of the energy of an electric discharge in a dielectric gap (barrier), or formed from oxygen in the air under the influence of radiation from ozone-forming UV lamps that generate ozone, disinfects surfaces and has a deodorizing effect. Obtained in the ozonizer 10 or generated under the influence of ultraviolet radiation from UV lamps installed instead of the ozonizers 10, ozone enters the garbage container 2 and part of it spreads through the inside of the caisson 1. When it comes into contact with garbage, ozone, as a strong oxidizer, reacts with pollution on the surface of the debris, attaches to the molecules of the pollutant and destroys their structure.

The aforementioned ozone-free germicidal UV lamps 11, which are installed at the entrance to the exhaust ventilation 7 SPHM in front of the fans 15, have an ultraviolet radiation wavelength from 205 nm to 315 nm, a peak of 265 nm. Ozone-free germicidal UV lamps 11 also serve for additional disinfection of air entering forced exhaust ventilation 7, deodorization and elimination of unpleasant odors. Ozone-free germicidal UV lamps 11 are located at the entrance to the forced exhaust ventilation, preferably at the rear wall 23 of the caisson 1 near the floor in the lower part of the caisson 1, where the inlet 26 for the intake of air and ozone is located. The inlet channel 26 is equipped with an electrically driven damper 27 that closes the entrance to the forced exhaust ventilation 7 when the SPHM is inoperative. At the outlet from the forced exhaust ventilation 7, if necessary, there can also be anti-ozone filters. The number of forced draft ventilation channels 7 depends on the length of the caisson 1 and can be from one to four.

The processing of garbage in garbage containers 2, as noted above, is carried out due to the supply of ozone from ozonizers 10 or UV lamps that generate ozone. For uniform processing, as the garbage enters the garbage container 2, the garbage should enter in open, not tied bags. If the use of bags (or bags) for garbage is allowed, the SPXM is equipped with a mechanism 13 for tearing bags (or bags), hereinafter - a mechanism 13 for tearing bags, i.e. a device that breaks and / or shreds bags, located under the urn 8. For this, under each urn 8, the above-mentioned mechanism 13 for tearing garbage bags is installed. Each bag tearing mechanism 13 has from two to four toothed blades, reciprocating and damaging, tearing garbage bags, as well as a drive in the form of electromechanical actuators. The actuator can in particular consist of an electric geared motor and a toothed rack.

Above the bag tearing mechanism 13 is a gate 9, which closes the lower opening of the urn 8. Gate 9, in a position that overlaps the lower opening of the urn 8, prevents ozone from entering the space of the urn 8 from the space of the caisson 1 into the space of the urn 8 and its exit. Gate 9 opens the hole under the urn 8 when the bags from the urn 8 fall onto the gate 9, while the command to turn on the gear motor by the mechanism 13 of tearing the packages under the corresponding urn 8 comes from the sensor with the photocell 21 located above the gate. The signal from the sensor turns on the gear motor of the mechanism 13, which moves the toothed rack with the toothed blades attached to it, i.e. the mechanism 13 of tearing the bags is triggered.

In the initial position, the toothed blades of the mechanism 13 are extended, in the retracted position, the toothed blades, moving and tearing the garbage bags, completely free the hole under the trash can for the garbage to fall from the bags into the garbage containers 2. The mechanism 13 of tearing the bags serves to remove ozone from the ozonizers 10 or UV lamps that generate ozone could constantly penetrate between the fragments of solid waste or MSW in a free-flowing state, freed from bags, and effectively decontaminate the waste.

The operating procedure of the SPHM equipped with 10 ozonizers or UV lamps that generate ozone, as well as ozone-free bactericidal UV lamps 11.

Start of work of SPHM. In the initial position, the cage 4 is inside the caisson 1. Waste containers 2 are cleaned and not loaded with garbage. Ozonizers 10 (or UV lamps that generate ozone) installed on the back of the bins 8 are turned off and raised by actuators 19 to the upper position. Ozone-free germicidal UV lamps 11 installed at the entrance to forced exhaust ventilation 7 are turned off. Gate 9 and bag tearing mechanism 13 are located under urns 8 in an extended position, blocking the hole under the urn. Forced exhaust ventilation 7, which includes a built-in duct fan 15, is disabled. The motorized damper 27 is in the closed position, the intake of air and ozone from the lower part of the caisson 26 is closed.

Start of work of SPHM. Ozonizers 10 (or UV lamps that generate ozone) installed in the casings 20 near the urns 8 are turned on and lowered by the actuators 19 to the lower position. The lower part of the ozonizers 10 (or UV lamps generating ozone) is located inside the garbage containers 2 (ozone enters the inside of the containers 2). Ozone-free bactericidal UV lamps 11 installed at the entrance to forced exhaust ventilation 7, carrying out ozone destruction (conversion of ozone into diatomic oxygen), are switched on.

Forced exhaust ventilation 7 with built-in duct fans 15, included. The damper 27 with an electric drive is in the closed position, thus blocking the inlet channel 26 for intake of air and ozone from the lower part of the caisson 1. Air enters from the outside through the slot between the caisson 1 and the upper platform 5 of the stand 4. The slot is located along the perimeter of the upper platform. Further, air from the slot enters the exhaust ventilation duct 14. The exhaust ventilation box 14 is located along the perimeter of the upper platform 5 of the stand 4 along the slot. The box has openings for air intake along its entire length. The gap between the caisson 1 and the upper platform 5 of the stand 4 also receives air and partially ozone from the caisson 1.

Air in the exhaust ventilation box 14 also enters through the exhaust ventilation box 16 located around the perimeter of the urns 8 (see Fig. 4). Box 16 also has openings along the entire length for air intake from ballot boxes 8. Thus, ozone does not have the ability to leave the box outside, as well as exit through the gap between the upper platform of cage 5 and chute 12 located along the perimeter of the upper platform 5 of cage 4 (see Fig. 1A, which shows unit A in Fig. 1).

A variant is possible when the design of the SPHM does not provide for the gate 9 and the mechanism 13 for tearing the bags (see Fig. 5), in this case, air and partially ozone enter the exhaust ventilation through the air intake 32 located near the bottom of the urns 8 (see Fig. . five). Exhaust takes place through exhaust ventilation 29 and tee 28 (see Fig. 5). Thus, a negative pressure is created inside the caisson 1, and ozone cannot escape from the urn 8 to the outside, as well as exit through the gap between the upper platform of the stand 5 and the chute 12 located along the perimeter of the upper platform of the stand of Fig. 1, view A.

When MSW or MSW enters the bins 8, a sensor 21 with a photocell is triggered. The gate 9 located under the bins 8 moves to the side, freeing up the passage for MSW or MSW, which fall on the mechanism 13 of tearing the bags. The mechanism 13 for tearing bags also moves to the side, during movement tearing garbage bags with serrated blades and freeing up the hole in the bottom of the bins 8 for the bags to fall into garbage containers 2.

Operation of 10 ozonizers or UV lamps that generate ozone. Ozonizers 10 or UV lamps that generate ozone operate in on / off cycles. The duration of the periods of on and the periods when the ozonizers and UV lamps that generate ozone are turned off are selected experimentally. After ozone fills the garbage containers 2, it begins to fill the space of the caisson 1, disinfecting the walls of the garbage containers and the floor of the caisson, cage 4, hydraulic cylinders 38 and vertical guides 39.

Work of SPHM before raising stand 4 and unloading garbage from garbage containers 2 into a garbage truck. Three hours before unloading garbage from garbage containers 2 into a garbage truck, a timer goes off. Ozonizers 10 (or UV lamps generating ozone) are switched off. Forced exhaust ventilation 7, incl. built-in duct fan 15 and ozone-free germicidal UV lamps 11 are on and continue to work. The damper 27 with an electric drive is switched to the open position, air and ozone are taken from the lower part of the caisson through the inlet 26 of the forced exhaust ventilation 7.

After three hours, forced exhaust ventilation 7 with built-in duct fans 15 is turned off, the motorized damper 27 moves to the closed position, ozone-free UV germicidal lamps 11 installed at the entrance to forced exhaust ventilation 7 are turned off.

Further, at the command of the operator through the control panel located in the control stand, a command is given to the hydraulic station and the hydraulic cylinder raises the stand 4 to the upper position. Garbage containers 2 are unloaded into a garbage truck and cleaned are returned to cage 4. Further, at the operator's command through the control panel, cage 4 is lowered to the lower position, and the operating procedure of the SPHM equipped with ozonizers 10 (or UV lamps generating ozone) and ozone-free bactericidal UV lamps 11 is repeated ...

Claims (19)

1. A system of underground waste storage, containing a caisson, in which a cage for garbage containers is installed, which has the ability to move vertically by means of the cage movement mechanism and is formed by a force set connecting the horizontal lower platform of the cage with its upper platform, which overlaps the inside of the caisson when the cage is lowered into the extreme lower position, while at least one hole is made in the upper platform, above which an urn is fixed, characterized in that the system is equipped with at least one disinfection means generating ozone, installed on the upper platform with the possibility of vertical movement in the direction the inside of garbage containers installed under the trash can. 2. The system according to claim 1, characterized in that the ozone-generating disinfectant is made in the form of an ozonizer or a UV-lamp that generates ozone. 3. The system according to claim 2, characterized in that the casing, in which the disinfection means generating ozone is installed, is attached to the urn and is open on the inside for lowering and lifting the disinfection means and is made with openings for air intake from the outside, located above top platform. 4. The system of claim. 1, characterized in that the stand is made, at least, with one opening between the vertical drains, forming the power set. 5. The system according to any one of paragraphs. 1-4, characterized in that it is equipped with forced exhaust ventilation, equipped with ozone-free germicidal ultraviolet lamps installed at its entrance. 6. The system according to claim 1 or 5, characterized in that the number of garbage containers is from one to eight, and each garbage container is equipped with wheels for moving it. 7. The system of claim. 1, characterized in that the urn is equipped with an opening / closing means, namely a lid with a lock, and a gap is formed between the lid and the urn. 8. The system according to claim 1, characterized in that exhaust ventilation is located along the perimeter of the upper platform, which is a gap between the caisson and the upper platform of the stand. 9. The system of claim. 1, characterized in that a tray for water drain is located along the perimeter of the upper platform. 10. The system according to claim 5, characterized in that the forced exhaust ventilation is equipped with a built-in duct fan. 11. The system according to claim 10, characterized in that the forced exhaust ventilation is equipped with an anti-ozone filter. 12. The system of claim. 1, characterized in that the mechanism for moving the stand is made in the form of a hydraulic lift with hydraulic cylinders powered by a hydraulic station located in a metal body outside the caisson. 13. The system according to claim 2, characterized in that the disinfection means in the form of an ozonizer or a UV lamp that generates ozone is installed on an actuator fixed in the casing and which removes the disinfectant from the casing and lowering it into the trash container and lifting it out of the trash can container back into the casing. 14. The system according to claim 1 or 13, characterized in that the ozone generating UV lamps are installed in a metal mesh casing. 15. The system according to claim 1, characterized in that ozone-free germicidal UV lamps located at the entrance to the forced exhaust ventilation are installed at the rear wall of the caisson in its lower part near the horizontal lower platform, where the entrance to the forced exhaust ventilation is also located. 16. The system according to claim 1 or 15, characterized in that the entrance to the forced exhaust ventilation is equipped with an electrically driven damper that closes the entrance to the forced exhaust ventilation when the SPHM is inoperative. 17. The system according to claim 1 or 15, characterized in that the number of forced draft ventilation channels is from one to four. 18. The system according to claim. 1, characterized in that it is equipped with a mechanism for tearing bags or packages located under the urn, while the said mechanism is made with toothed blades mounted with the possibility of reciprocating motion, and the drive of the mechanism is made in the form of an electromechanical actuator, containing an electric geared motor and a gear rack. 19. The system according to claim 18, characterized in that it is equipped with a gate located above the bag or bag tearing mechanism, wherein the gate is movable from a position overlapping the hole above which the urn is installed to a retracted position when said hole is completely open.

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