RU2813876C1 - Scheme of integrated wasteless processing of municipal and industrial wastes - Google Patents

Abstract

FIELD: processing and recycling of wastes.

SUBSTANCE: invention relates to processing of solid municipal and industrial wastes, can be used directly at landfills for decontamination of landfills and their reclamation of both previously filled and newly formed wastes, for stabilization of the ecological situation of the territory adjacent to the landfill, providing the recultivation process. Complex for non-waste processing of municipal and industrial wastes for decontamination and reclamation of landfills includes solid waste sorting equipment with containers for storage of sorted wastes arranged in landfill, their preliminary treatment for secondary use or recycling. Complex is located in separate rooms inside non-permanent building structure and is equipped with a bio-farm with piles for growing an adapted culture of the red Californian worm on bio-fodder from food wastes of sorting. At the same time the complex is additionally equipped with a lateral road around it, a trench for laying biological wastes for processing into humus with subsequent planting of coniferous trees, equipment for production of products from raw materials obtained as a result of processing of solid household wastes. Containers for storage of sorted wastes are made of easily destructible and processed material, which themselves at the end of the waste recycling cycle fall into the category of solid municipal wastes and are processed in the next waste processing cycle.

EFFECT: invention provides the environmental improvement due to the elimination of hazardous gases arising from the incineration of garbage, and by reclamation of the land under the municipal dump, due to preparation of fertile soil layer in trench and planting of coniferous forest.

4 cl, 7 dwg

Description

The invention relates to the field of processing solid municipal and industrial waste; it can be used directly at landfill sites for the neutralization of landfills and their reclamation of both previously filled and newly generated waste, to stabilize the environmental situation in the area adjacent to the landfill, ensuring the reclamation process.

There is a known method for processing waste from city landfills (patent No. 2253668, IPC C10L 5/46, B09B 3/00, 11/12/2003, op. 06/10/2005 Bulletin No. 16), which consists in profiling the landfill area in the process of garbage accumulation and excavation waste from the landfill, waste sorting with the separation of scrap metal, stones and non-combustible construction waste, briquetting after sorting the remaining waste, after profiling, the landfill area is divided into technological sites, which are sprinkled with peat and, if available, sawdust, waste sorting is carried out by layer-by-layer cyclic surface processing of technological sites with the fangs of rotary peat stump uprooters and then the working parts of stone removal road construction machines with simultaneous mixing of peat and in the presence of sawdust with debris along the depth of the sites and shaking on separators of large and then small metal scrap, stones and non-combustible construction waste, filling them in machine bunkers for further removal outside the landfill, and the cleaned garbage mixed with peat and, if present, sawdust, is subjected to surface grinding by layer-by-layer milling with a complex of peat milling machines; the milled garbage crumbs mixed with peat and, if present, sawdust are dried under solar radiation in in the summer season or by freezing out moisture in the winter season and removed in accordance with the technology for harvesting milled peat for further storage in stacks and briquetting into household fuel.

The disadvantage of this known method is that it does not solve the problem, since combustion produces gases harmful to the human body, and slag removal implies the presence of toxic solid waste, the toxicity class of which is higher than that of garbage, which leads to environmental deterioration.

A known system for complex non-waste processing of solid and industrial wastes through their high-temperature conversion in a reactor with allothermic heat supply and liquid slag removal (patent No. 2 648 737, IPC B09B 3/00, dated 12/08/2016, op. 03/28/2018 Bulletin No. 10) , which includes technologically interconnected: a shaft-type counterflow reactor, into which solid waste is supplied through preparation, loading and loading locks; a high-temperature heater, from which hot blast in the form of water vapor, heated to a temperature of at least 1700°C, flows into the reactor through a supply lance with an annular gas duct, providing allothermic heat supply; vents located below the tuyere for releasing molten minerals and molten metals, respectively; exhaust annular gas outlets located above the tuyere and equipped with dampers to regulate the removal of conversion products from the reactor: raw synthesis gas and raw pyrolysis gas, respectively; filter for removing solid particles from raw synthesis gas; a heat reclaimer for raw synthesis gas to meet technological needs, including the production of water steam used to pressurize the locks to equalize the pressure with the pressure in the reactor; raw synthesis gas drying unit; a gas separator for separating carbon dioxide from synthesis gas; receiver for collecting purified and dried synthesis gas; a purification unit for removing solid particles, fatty and tar contaminants, as well as chlorine, fluorine and sulfur containing impurities from raw pyrogas; purified pyrogas drying unit; container for collecting purified and dried pyrogas; gas mixer for obtaining a normalized combustible mixture from purified and dried synthesis gas and pyrogas; a gas holder for accumulating a combustible mixture used in the combustion chambers of a high-temperature heater and a gas turbine power generating unit to supply energy to the claimed system; a steam generator for powering a high-temperature heater with water vapor with temperatures up to 500°C; a water treatment unit for the steam generator, receiving recharge from an external source and using water from the circulating water purification unit; a low-grade heat reclaimer to meet utility needs, using the heat of combustion products from a high-temperature heater and a gas turbine power generating unit; loading unit for returning grease, tar contaminants and solid particles from filters to the reactor.

The disadvantage of the known system is that it does not solve the problem, does not meet established environmental requirements due to the high values of the removal of harmful gases, including dioxins, dust and ash, which, as they accumulate, need to be buried somewhere, which means the technology cannot be called waste-free and is harmful to human health

The closest in technical essence to the claimed technical solution is a complex for sorting and processing solid municipal waste for the neutralization and reclamation of landfills (patent No. 80784, IPC B09B 3/00, dated 10.22.2008, op. 02.27.2009,  Bulletin No. 6) , which includes sequentially installed sections of solid waste sorting equipment, their pre-processing for recycling or disposal, and a storage facility located at the landfill site. The complex is located in separate rooms inside a non-permanent building structure and is equipped with a biofarm with piles for growing an adapted culture of the Californian red worm using biofeed from sorted food waste.

The complex is equipped with a heating pipeline laid in a trench of a landfill with an introduced culture of the red Ural worm, modified and adapted (KUCHMA) to the organic matter of the region, which is connected to a boiler located in the complex that uses fuel oil obtained from waste - used motor oil with the addition of diesel fuel .

Based on the results of a number of technical and biological works, the land is returned to general economic use.

The disadvantage of the known system is that it does not solve the problem and does not meet established environmental requirements due to the high levels of harmful gases produced when burning waste, including dioxins, dust and ash, which, as they accumulate, need to be stored somewhere. then bury it, which means the technology cannot be called waste-free and is harmful to human health.

The problem underlying the invention is to solve the problem of improving the ecology of the environment by eliminating harmful gases generated by burning garbage, and by reclaiming the land located under the city dump by preparing the fertile layer of soil in a trench and planting a coniferous forest.

The solution to this problem is achieved by the fact that the complex for sorting and processing solid household waste for the neutralization and reclamation of landfills, including sequentially installed sections of solid waste sorting equipment located at the landfill site with containers for storing sorted waste, their pre-treatment for recycling or disposal, located in separate rooms inside a non-permanent building structure, equipped with a biofarm with piles for growing an adapted culture of the Californian red worm on biofeed from sorted food waste,

additionally equipped with a rolling road laid around the complex, a trench for laying biological waste for processing into humus with subsequent planting of coniferous trees, equipment for the production of products from raw materials obtained from the processing of municipal solid waste,

containers for storing sorted waste are made of easily destructible and recyclable material, which themselves, at the end of the waste disposal cycle, fall into the category of solid municipal waste and are processed in the next waste recycling cycle;

heating of the biofarm for growing an adapted culture of red Californian worm is carried out using air, which allows maintaining 15-25°C, humidity 70-80% for an adapted culture of red Californian worm.

The presence of a roundabout, bypass road laid around the complex and consisting of appropriate sorted inert construction waste ensures the functioning of the proposed system for integrated waste-free processing of municipal and industrial waste, and creates the opportunity for the movement of tractor carts after unloading in trenches.

Laying a trench for laying biological waste for processing into humus provides conditions for the subsequent planting of coniferous trees, which directly solves the problem of improving the ecology of the environment and the further use of natural resources by reclaiming the land located under the city landfill, and in the foreseeable future, obtaining commercial timber from the planted formerly trees.

The use of containers for the collection, transportation and storage of sorted waste, solid municipal and industrial waste, is made of durable metal-plastic structures, which themselves, at the end of the waste disposal cycle, fall into the category of solid household waste and are processed in the next waste processing cycle, creating a resource for the further production of assembly parts of containers .

The economical and technological design of containers, capable of being transformed into components of other municipal structures, will also make it possible to create economical municipal facilities in the same style, for example, container sites, enclosing structures, street tanks for collecting municipal waste.

Heating of the biofarm for growing an adapted culture of the red Californian worm is carried out using hot air, providing it with a temperature of 15-25°C, a humidity of 70-80% for an adapted culture of the red Californian worm. Air replaces water, because water, as a coolant, freezes in winter, so it was replaced with hot air.

Heating of two trenches of a biofarm for processing organic waste into humus using an adapted culture of the red Californian worm and the supply of allowing air that maintains a temperature regime in the trench of 50-60 ° C, humidity 50-70% for bacteria and 15-25 ° C, humidity 70- 80% for the adapted culture of the red Californian worm, allows this process not to be stopped in the winter season and activates the decay of organic waste, improving the living conditions of the worm, creating a natural reserve for autumn or spring planting of forests on the former landfill site.

In fig. 1 shows a diagram of the sorting complex and technology for processing solid municipal and industrial waste,

in fig. Figure 2 shows a cross section of a trench filled with organic waste,

in fig. 3 shows a cross-section of the rock road,

in fig. Figure 4 shows a plant for processing used tires into reinforced asphalt,

in fig. 5 shows a diagram of a complex for processing solid municipal and industrial waste with a trench and a rock road (top view),

in fig. 6 shows a drawing of a transforming tank,

in fig. Figure 7 provides an illustration of a circular economy - a system for collecting, transporting, sorting and recycling household and industrial waste.

The complex of sorting and processing technology for solid municipal and industrial waste (Fig. 1) consists of:

1 – overpass for the first stage of sorting, mainly large-sized waste into tractor carts;

2 - fixed platform for sorting solid municipal and industrial waste;

3 - mobile platform for sorting solid municipal and industrial waste;

4 – cable tipper;

5 – loading hatches of the right sorting area;

6 – cart for waste wood, chipboard, fiberboard, etc.;

7- cart for combined waste, tires, electronic waste and spare parts for them, shoes, complex toys and other waste that requires separation into its component parts;

8 - cart for inert construction waste, cements and putty, roofing felt, linoleum and other waterproofing waste, varnishes, paints, solvents and motor oils;

9 – cart for organic waste, food waste of plant and animal origin, all vegetation, dirty paper and rotting textiles;

10 – sorting module;

11 – left conveyor of solid household and industrial waste;

12 - right conveyor of solid household and industrial waste;

13 – reverse conveyors of “tails”;

14 - press;

15 – area for the production of polymer-sand paving slabs and tiles from the same material for completing container sites for the collection of solid household and industrial waste;

16 – waste paper in bales;

17 – plastic in bales;

18 – leather and rubber in bales;

19 - textiles in bales;

20 – metal containers for ferrous and non-ferrous metals;

21 – industrial wood and firewood for waste heat boilers;

22 – site for the production of toilet paper and waste paper;

23– biofarm;

24 – collars;

25 – biologist’s laboratory;

26 – trenches for laying biological waste for processing into humus with subsequent planting of coniferous trees;

27 – rolling road for laying construction and inert waste;

28 – boiler room for heating the Complex and heating the air supplied to the trenches in the cold season.

A cross section of a trench filled with organic waste (Fig. 2) consists of:

29. Household waste dump.

30. Trench filled with organic waste.

31. Dense covering material to retain heat and moisture.

32. Wooden ladder for fixing plastic pipes for analysis of organic processing.

33. Pipe for a thermometer.

34. Pipe for gas analyzer

35. Pipe for taking samples for humidity, presence of bacteria and vermiculture.

36. Perforated plastic pipe for irrigation in the warm season.

37. Perforated plastic pipe for collecting landfill gas.

38. Two perforated plastic pipes laid on pressed “tails” with fixation recesses to prevent sliding to the bottom of the trench when unloading organic matter.

39. Water supply funnel in the warm season.

40. Water ring vacuum – pump for pumping out landfill gas.

41. Pressed “tails” that improve trench aeration.

The section of the rock road (Fig. 3) consists of:

42. Vegetation cover.

43. Gravel, broken brick, crushed stone, cement residues, dry mixes and other binders.

44. Large stones, hardened cement, fragments of curbs and similar construction waste.

45. Foundation blocks, reinforced concrete products, blocks of hardened mortar.

46. Linoleum of all sizes, roofing felt, dirty polyethylene film of any thickness and chemical composition.

47. Non-recyclable waste today is, if possible, moisture-resistant.

48. “BODY” of a landfill – the entire amount of waste located on the territory of the landfill.

49. Pedestrian path along the entire perimeter of the landfill.

50. Fiberboard, chipboard, plasterboard and other wall materials.

51. Reinforced asphalt made from tires using the author’s technology at a plant for processing used tires into reinforced asphalt.

52. “TAILS” of inert waste, compressed into rectangles and preferably packed in plastic film.

Plant for processing used tires into reinforced asphalt

(Fig. 4) consists of:

53. Upper half flap of the heating chamber.

54. Tire suspension rail.

55. KAMAZ tire and others of this size.

56. Gravel heated to 200°C.

57. Furnace firebox.

58. Tire for ZHIGULI and other cars of this size.

59. Grate.

60. Chimney.

61. Manual asphalt mixer.

62. Tire cords are used as asphalt reinforcement.

63. Winch for lifting and lowering gravel and sand, as well as for extracting tire cords.

64. Hand winch boom.

65. Blower and ash pan of the stove.

66. Tire supply overpass.

67. Tar loading gate.

68. Sand heated to 200 degrees C.

69. Winch for supplying tires to the melting zone.

70. Skids for moving the installation as asphalt is laid on the rock road.

The diagram of a complex for processing solid household and industrial waste with a trench and a rolling road (Fig. 5) consists of:

71 – landfill for production and consumption waste;

72 – two parallel trenches filled with organic waste;

73 – complex for sorting and processing solid household and industrial waste;

74 - rock road along the entire perimeter of the landfill.

The transforming tank (Fig. 6) consists of:

75 – metal-plastic side walls;

76 – metal-plastic tank bottom;

77 – plastic wheels;

78 – tank fixation unit during unloading;

numbers are attached to the top crossbar of the tank wall: 07 is the number of the city district, 013 is the number of the container site in this area, 01 is the number of the tank on this site (for trash cans this number can be three-digit).

The telephone number of the regional operator or management company is attached to the lower crossbar for SMS messages from citizens that the tank is full, broken or overturned for prompt intervention by the responsible persons. Based on the number of such messages, the city administration will determine the quality of work of the regional operator or management company.

The circular economy scheme in the field of municipal solid waste management is shown in (Fig. 7) and includes:

79 – generation of solid municipal and industrial waste during the operation of small and medium-sized businesses; social, cultural and everyday organizations; from trade activities and from the life of the population;

80 – collection of solid municipal and industrial waste into transformer tanks;

81 – removal of solid municipal and industrial waste;

82 – sorting of solid municipal and industrial waste. All 100% of waste is sorted using two-stage technology and disposed of;

83 – hazardous waste, medical, chemical power sources, light bulbs of all modifications;

84 – organic waste, in which, after processing into fertile soil, future industrial wood is grown;

85 – secondary material resources – waste paper, plastic, glass, metals, textiles, leather and other waste;

86 – disposal of solid municipal and industrial waste:

87 – processing of secondary material resources into goods for personal use

needs of the complex and for sale to the public;

88 – sale of secondary material resources to enterprises for the manufacture of goods and products.

Collection of solid municipal and industrial waste is carried out in transformer tanks (Fig. 6).

This technology is based on working only with solid municipal and uncompacted industrial waste, therefore, this technical process eliminates garbage trucks, which turn solid municipal waste into garbage, which leads to the loss of raw materials for processing and the proliferation of landfills.

On the container platform 80 these tanks – transformers fig. are installed. 6 based on serving 200 residents, nearby houses for one tank with a volume of 1 m ³ , the specific gravity of solid household waste on average in Russia is 200 kg/m ³ , and one tank (not shown in the figure) for hazardous waste, to work with Only companies that have licenses to collect, transport, process and dispose of hazardous waste are allowed.

Transformer tanks (Fig. 6) are stamped in thermoplastic machines from plastic waste with a metal frame.

The side walls 75 of the tank are strictly vertical, and the wheels 77 are permanently mounted on the bottom of the tank 76 without a trolley platform. Since the walls of the transforming tank are absolutely identical, only two molds are required - one for the side walls and the second for the bottom, which reduces the cost of tooling in the manufacture of these products.

The economical and technological design of the tanks, capable of being transformed into components of other municipal structures, will also make it possible to create economical municipal facilities in the same style, for example, trash cans, container platforms, enclosing structures, and also, it is planned to place a black plastic bag, rectangular in shape, in each tank , repeating the shape of the tank with a 10% margin in height for tying the bag after full or partial filling before transportation with a disposable plastic clamp. This will reduce the ingress of precipitation, the appearance of birds and insects and will prevent waste from scattering during transportation from the container site to the Complex, and all used bags will be recycled into the side walls of tanks or bins. Container platforms are also made from the side walls of tanks 75, obtained by attaching the side walls of the tanks to a metal frame.

Solid municipal waste is delivered to sorting complex 82, the machine enters the first stage overpass, where bulky waste is collected. Transformer tanks are unloaded onto platforms with sorting hatches 5 of the first stage. Next, each tank is installed on a movable municipal solid waste sorting platform 3 and tipped onto it. The empty tank is lowered down from the overpass to be installed on the next machine.

The advantage of the proposed technology is that garbage trucks with a waste pressing mechanism are excluded from this process. Container ships 81 with a volume of 30 m ³ and 40 m ³ are used, on which the tanks are installed in two rows and two tiers with a total volume of 20 m ³ fig. 7. Then solid municipal waste will be as clean as possible, which means it will be more economically profitable for the extraction of secondary material resources, and therefore profit.

It is proposed to transport unpressed solid municipal waste on vehicles similar to the Chinese JAK 80 with a hydraulic lift of up to 500 kg 81, on which the tanks are installed in two rows and two tiers with a total volume of 20 m ³ fig. 7. Unloading can be done using the same lift at pre-sorting site 1.

Sorting of solid municipal waste occurs in two stages: if the car is loaded with tanks, then, having climbed the overpass 1, the car is unloaded using a cable crane beam, which is also a cable tipper 4, onto the far movable platform 3 and the side platform 5, equipped with metal covers , but if a KAMAZ with a body of 40 m ³ arrives, then it goes to the mobile solid municipal waste sorting platform 3 and the fixed municipal solid waste sorting platform 2, which facilitates the work of the first stage sorters. Through loading hatches 5 on the right side, all waste is dumped through hatches into carts 6 - 9 located under the overpass: a cart for waste 6 wood, chipboard, fiberboard, etc. will go to boiler room 28 for processing into firewood. Trolley 7 for combined waste, electronic waste and spare parts for it, shoes, complex toys and other waste that requires separation into its component parts is sent to the disassembly site into its component parts with subsequent disposal of the selected secondary material resources. Trolley 8 for inert construction waste, cements and putty, roofing felt, linoleum and other waterproofing waste, varnishes, paints, solvents and motor oils is sent to fill the road 74.

Trolley 9 for organic waste, food waste of plant and animal origin, all vegetation, dirty paper and rotting textiles is sent for unloading into trenches 72 (26) of organic waste to obtain humus with subsequent planting of industrial tree species.

The total mass of such waste will be from 40 to 60% of solid municipal waste, which allows maintaining the purity of future secondary material resources and will facilitate sorting at the second stage, when cable tippers 4 will tip the remaining waste onto conveyors 11 and 12, located on the floor below. This is where the final selection of the remaining types of solid municipal waste takes place: paper and cardboard, plastic, glass, leather and rubber, textiles and black and non-ferrous metal. Hazardous waste is collected separately: HITS - chemical power sources, light bulbs of all types and designs and medical supplies that have become unusable.

After this, so-called “tails” remain on conveyors 11, 12 - small fractions of cullet, scattered dry mixtures, stones and debris of all types of waste, etc. In order to dispose of them, at the end of each transport conveyor 11, 12 it is proposed to mount reverse conveyors 13, which will allow sorters to divide this mass of waste into two parts. The one in which there is more organic waste is sent to press 14, in which supports with recesses for laying and fixing heating pipes 38 are made, and everything else is pressed into bales to fill the lower layer of the rolling road 52.

Two trenches 30 are dug by a bulldozer to a depth of 1 meter and pressed “tailings” 41 are laid at the bottom of the trench at intervals of one meter - having grooves for fixing the perforated pipe 38, which improve the aeration of the organic waste of the trench over 30-60 or 90 meters, depending on amount of exported organic matter. After the conversion of organic matter into humus is completed, they are removed and transported using a tractor for subsequent use for their intended purpose.

To preserve heat, moisture and collect landfill gas from secondary material resources, dense covering material 31 is sorted and a perforated pipe 37 is laid to pump out landfill gas using a liquid ring pump 40.

To control the regime in the trench, a thermometer installed on pipe 33 and a gas analyzer on pipe 34 are used. Humidity, the presence of bacteria and vermiculture are monitored by taking samples through pipe 35. Plastic pipes are installed to analyze the processing of organics 33 - 35 on a wooden ladder 32.

Heating the trench allows you to maintain a temperature of 50-60°C, humidity 50-70% for bacteria and 15-25°C, humidity 70-80% for an adapted culture of the red Californian worm.

Into the resulting compost we release vermiculture adapted to this type of waste - a culture of the Californian red worm, grown on a biofarm in an amount sufficient to process the incoming organic waste to the landfill. Worms transform compost into vermicompost, which is rich in metabolites - plant growth regulators - auxin, gibberellin, cytokinin, proteins and amino acids, which accelerates the survival and growth of pine seedlings.

After 3-4 months, trenches 30 are filled with overburden soil, mixed and planted with seedlings in a checkerboard pattern. It is the planting of pine trees, and most often forests once grew in place of landfills, that allows us to call this system of technologies a closed-cycle economy, since in 30-50 years three-year-old pine seedlings will turn into commercial timber.

The presence of a rock road fig. 4 ensures the functioning of the complex by transporting waste both to the road itself and organic matter to the humus production trenches and returning tractor carts to the complex.

A rock road is laid along the perimeter of the landfill with a width of 3 m and a depth of 1.5-2.0 m - for the disposal of construction waste, blocks of solid municipal waste, the disposal of which seems costly or problematic. The dug pit is lined with wall material 50 type fiberboard, plasterboard, and “tails” of inert waste 52 are placed down the pit, pressed into rectangles, preferably packed in plastic film. Next, waste 47 that is not currently recyclable is stored and, if possible, moisture-resistant. Then this layer is covered with waste roofing felt, linoleum, and polyethylene film 46. Reinforced concrete products and foundation blocks 45 are laid on layer 46, ensuring the density of the road. Large stones, hardened cement and other similar construction waste are poured in the next layer 44 onto the foundation blocks 45 of the road. To level the road surface, the top layer is formed by a scattering of gravel, crushed stone, cement residues and the like, construction waste. The rock road is asphalted with reinforced asphalt made from tires at a plant for processing used tires into reinforced asphalt directly at the landfill. Next to the road there is a pedestrian path 49 for the complex's maintenance personnel.

The plant for processing used tires into reinforced asphalt is a completely autonomous design without electrical equipment, running on wood waste and associated gas obtained from melting tires to produce tar and can be manufactured at the Complex itself - since it has a simple design and does not require large costs.

The basis is a used railway container 12 m long and 4 m wide. A pipe 53 with a diameter of 140 cm, the outer diameter of a KAMAZ tire is 112.2 cm, and a rail 54 at an angle of 15 degrees is mounted inside.

Tires are cut to simplify the suspension on the rail - and the tires are sorted and hung, alternating large 55 and small from Zhiguli 58 - for faster heating and softening of tires in quantities of up to 20 pieces. using tire supply rack 66.

Sand 68 and gravel 56 are heated on the roof of the container to at least 200 ° C and fed through gate 67 into asphalt mixer 61, where they are mixed with liquid tar, which drains when the tires are heated. The furnace firebox 57 allows you to burn both old wooden pallets and halves of doors and windows until metal or nylon cords 62 remain on the tire suspension rail. They are attracted by a winch 69, and then lifted using a feed winch 63, and laid on compacted inert waste , and cover the top with the resulting three-component asphalt - 40% tar, 30% sand and 30% crushed stone, up to 10 cm thick and roll it with a hand roller.

After processing the next batch of tires, the installation is moved using a bulldozer on skids 70 to a new location along the road and the next batch is loaded.

In this case, the road can also act as a product, and this installation can be used for the construction of temporary roads in gardens and vegetable garden cooperatives

In Fig. 5, in the top view, you can see the plan of the Solid Waste Processing Complex. As you can see, inside the rock road 74 there is a landfill itself, around which two parallel trenches 72 are dug, filled with organic waste. A complex for sorting and processing solid municipal waste 73 was installed at the edge of the landfill.

The closed cycle of this economy is clearly visible in Fig. 7 “CLOSED CYCLE ECONOMY in the field of municipal solid waste management.” Small and medium-sized businesses, social, cultural and everyday organizations, trade, population 79 generate solid municipal and industrial waste daily, and this entire flow is stored at container sites 80, loaded onto vehicles 81 and delivered to the sorting complex 82, where it is separated for organic waste 84, secondary material resources (RMR) - textiles, waste paper, plastic, etc. 85. Hazardous waste 83 is separately selected and transferred for disposal to enterprises that have the appropriate license. Sorted waste is processed into goods and sold to the public, small and medium-sized businesses, and trade, which completes the circular economy scheme.

A technological complex for the production of paper products was used as equipment for the production of products from the raw materials obtained as a result of processing solid waste.

The results of the implementation of this invention:

- Transition to the collection and transportation of only solid municipal waste without the use of vehicles with presses that turn waste into garbage.

- Construction of the Solid Waste Sorting Complex using a two-stage technology makes it possible to bring sorting to 100% and recycling to 80-90% of the total mass of incoming waste.

- Laying 2 parallel trenches 72 for bio-waste, bio-farm equipment for propagation of an adapted culture of the red Californian worm, which can “work in a trench” and adapted to the bio-waste of a given city, allows for the disposal of organic waste, the production of humus, the planting of technical species of trees that in the future will grow into a commodity , which can be sold on the wood market.

- Placing inert waste, mainly construction and development waste, in the 74 road encircling the entire landfill allows for the disposal of construction waste without extra costs, while simultaneously building a temporary road along the entire perimeter of landfill 74 and to the nearest asphalt road.

- Waste paper processing areas are also installed at the Complex

into toilet paper, cardboard and other necessary products for sale to residents of a given city

Processing of plastic into paving slabs, polymer-sand tiles, as well as the production of tanks and trash cans, and other products from recycled plastic are in demand in this city

- Installations for processing used tires into reinforced asphalt were installed for recycling tires and paving the road along the entire perimeter of the landfill and to the nearest highway to improve the delivery of solid waste to the Complex.

- The planting of coniferous trees has been organized for the reclamation of this and nearby landfills in order to reduce infiltration in aquifers, convert carbon dioxide released by bacteria from the decomposition of biowaste into oxygen and obtain industrial wood after a certain number of years.

- The presence of numbers on tanks and ballot boxes will allow citizens to control the work of regional operators and management companies.

Claims (4)

1. A complex of waste-free processing of municipal and industrial waste for the neutralization and reclamation of landfills, including sequentially installed sections of solid waste sorting equipment located at the landfill site with containers for storing sorted waste, their pre-treatment for recycling or disposal, located in separate rooms inside a non-capital construction structures, equipped with a biofarm with piles for growing an adapted culture of the Californian red worm on biofeed from sorted food waste, characterized in that it is additionally equipped with a rolling road laid around the complex, a trench for laying biological waste for processing into humus with subsequent planting of coniferous trees, equipment for production products from raw materials obtained as a result of processing solid household waste, containers for storing sorted waste are made of easily destructible and recyclable material, which themselves, at the end of the waste recycling cycle, fall into the category of solid municipal waste and are processed in the next waste recycling cycle. 2. A complex for waste-free processing of municipal and industrial waste for the neutralization and reclamation of landfills according to claim 1, characterized in that the biofarm for growing an adapted culture of the Californian red worm is heated using air, which allows it to maintain a temperature regime of 15-25 ° C and humidity 70-80% for an adapted culture of the red Californian worm. 3. A complex for waste-free processing of municipal and industrial waste for the neutralization and reclamation of landfills according to claim 1, characterized in that a technological complex for the production of polymer sand tiles from metal and ceramic waste is used as equipment for the production of products from the raw materials obtained as a result of processing solid waste. 4. A complex for waste-free processing of municipal and industrial waste for the neutralization and reclamation of landfills according to claim 1, characterized in that a technological complex for the production of reinforced asphalt from recycled used tires is used as equipment for the production of products from the raw materials obtained as a result of processing solid waste.