WO2021173033A1

WO2021173033A1 - Waste reprocessing unit

Info

Publication number: WO2021173033A1
Application number: PCT/RU2021/000026
Authority: WO
Inventors: Юрий Алексеевич КОБАКОВ
Original assignee: Юрий Алексеевич КОБАКОВ
Priority date: 2020-02-25
Filing date: 2021-01-25
Publication date: 2021-09-02
Also published as: RU2724741C1

Abstract

A waste reprocessing unit comprises a low-temperature destruction reactor (1) with a spiral transporter (2), at an inlet of which a feeder (3) is installed, and at a first outlet (4) of the spiral transporter (2) a solid product discharge means (5) is installed which is connected to a receiver assembly (6) of the spiral transporter (2); the reactor (1) has a second outlet (7) for a flue gas pipe (8) and a third outlet (10) for a steam-gas mixture pipe (11), which is connected to a rectifying column (13), wherein the reactor has three zones — a first zone (20) in which material is supplied to the reactor, a second zone (21) where the material is heated and a third zone (22) where the material is destroyed; and the spiral transporter (2) has a spiral having an increasing spiral winding pitch, wherein the spiral of the spiral transporter (2) in the zone (22) where the material is destroyed has blades (19) which are mounted on the spiral windings and allow not only linear transport of the material but also vertical transport.

Description

Waste treatment plant.

Technology area

The proposed invention relates to the field of waste processing, in particular the processing of solid municipal waste containing a mixture of plastic, rubber, paper, polymer and medical waste, and can be used for waste disposal to obtain solid carbonaceous raw materials and other products for various industries.

The constantly growing amount of solid municipal waste creates the problem of their disposal and recycling.

Incineration or burial of these wastes requires significant energy consumption, leads to environmental pollution, as well as to the loss of organic, carbon-containing and metallic raw materials.

Prior art

Known installation for the processing of rubber-containing waste (patent RU N ° 2291168, C08J11 / 04), containing a reactor with a conveyor, at the entrance of which a feeder is installed, and a means for unloading a solid product is installed at the exit, while the reactor has an outlet for flue gas and an outlet for a pipeline steam-gas mixture.

The disadvantages of this installation are its technical complexity, high energy consumption and low efficiency. The closest in technical essence and the achieved result to the present invention is "Installation for the processing of rubber waste" according to patent RU Ny 2460743, C08J 11/20, selected as a prototype.

This plant for the processing of rubber-containing waste contains a low-temperature destruction reactor with a spiral conveyor, at the entrance of which a feeder is installed, and at the outlet a means for unloading a solid product is installed, while the reactor has a rubber crumb thermolysis section and a section for bringing carbon black to a commercial condition.

This waste treatment plant is much simpler to manufacture and operate than the one described above, but it has high energy consumption and low efficiency.

The essence of the invention

The objective of the proposed invention is to increase the efficiency of the waste processing plant while simplifying its design through the use of a spiral conveyor with an increasing pitch of the spiral, as well as due to the presence of blades on the spiral conveyor to intensify the process inside the reactor.

The technical result of this invention is to improve the efficiency of the installation while simplifying its design.

The task is achieved due to the fact that in a waste processing plant containing a low-temperature destruction reactor with a spiral conveyor, at the entrance of which a feeder is installed, and at the first outlet of the spiral conveyor, a means for unloading a solid product is installed, connected to the receiving unit of the spiral conveyor, the reactor has a second an outlet for flue gas and a third outlet for a pipeline of a vapor-gas mixture, which is connected to a rectification column, while the reactor has three zones, a first zone for feeding material into the reactor, a second zone for material heating, and a third zone for material destruction, and the spiral conveyor has a spiral with an increasing the pitch of the spiral turn, while the spiral of the spiral conveyor in the material destruction zone has blades installed on the spiral turns and made with the possibility of providing, in addition to the linear movement of the material, its vertical movement.

In a preferred embodiment, in a waste processing plant, the pitch "n" of the conveyor spiral is selected depending on the outer diameter "D" of the conveyor spiral in accordance with the ratio: n <D.

It is desirable that in an installation for waste processing, each subsequent step "n" of the conveyor spiral turn, in the material heating zone in the reactor, should increase by 10% from the previous step of the conveyor spiral.

It is advisable that a conical screw feeder with a spiral conveyor is used as a feeder in an installation for waste processing, which is made with the possibility of feeding into it crushed material of different morphological composition and moisture content, and at the same time providing a hermetic seal in the feeder when the crushed material is fed into it.

Preferably, in a waste treatment plant, the spiral conveyor of the screw feeder has loops, the diameter of which decreases from the inlet to the outlet of the conveyor of the screw feeder.

It is advisable that the installation for the processing of waste contains a filter located between the third outlet of the reactor and the pipeline of the steam-gas mixture. Desirably, in a waste treatment plant, the distillation column comprises a process water withdrawal section, a liquid hydrocarbon withdrawal section, and a hydrocarbon gas withdrawal section.

It is advisable that the waste treatment plant contains a jacket with burners for heating the reactor, placed around the reactor, while the jacket with burners was connected to the hydrocarbon gas extraction section with the possibility of entering the hydrocarbon gas into the burners for its combustion and thereby heating the reactor.

Brief Description of Drawings

For a more detailed disclosure of the invention, the following is a description of specific possible options for its implementation with the corresponding drawings.

FIG. 1 is a block diagram of a waste treatment plant according to the invention.

FIG. 2 is a fragment of a spiral conveyor of a reactor with blades, made according to the invention.

FIG. 3 is a sketch of a spiral conveyor of an increasing pitch reactor according to the invention.

FIG. 4 is a sketch of a conical screw feeder according to the invention.

Best options for carrying out the invention

The installation for waste processing contains a reactor 1 for low-temperature destruction with a spiral conveyor 2, at the inlet of which a feeder is installed 3, and at the first outlet 4, a means for unloading a solid product 5 is installed, connected to the receiving unit 6 of the spiral conveyor 2. Also, the reactor 1 has a second outlet 7 for a flue gas pipeline 8, which exits through a chimney 9, and a third outlet 10 for a steam-gas pipeline mixture 11, which is connected through a filter 12 to a distillation column 13 containing a section for the selection of technical water 14, a section for the selection of liquid hydrocarbons 15, and a section for the selection of hydrocarbon gas 16. At the same time, a heating jacket 17 of the reactor 1 with burners is placed around the reactor 1. connected to the section for the selection of hydrocarbon gas 16 through the pipeline of hydrocarbon gas 18, with the possibility of entering the burners of hydrocarbon gas for its combustion and thereby heating the reactor 1 (Fig. 1).

The reactor 1 has three zones, the first zone 20 for feeding material into the reactor, the second zone 21 for heating the material, and the third zone 22 for material destruction, while the spiral conveyor 2, in the zone 21 for heating the material, is made with an increasing pitch "n" of the spiral turn. That is, if the spiral conveyor 2 has a spiral turn pitch "p", then in the second zone 21 the conveyor 2 will have the first spiral turn pitch of 1.1 "p", the second spiral pitch will have a size of 1.2 "p", the third the step will be 1.3 "p" and so on. (Fig. 3).

In this case, the step "n" of the spiral turn of the spiral conveyor 2 is selected depending on the outer diameter "D" of the spiral of the conveyor 2 in accordance with the ratio: n <D.

Such a solution for the second zone 21 of heating the material avoids the formation of a plug, since the material in this zone has a temperature below the temperature of the beginning of its destruction, and at the same pitch of the spiral turn is prone to compaction. Throughout the entire length of the third zone 22 of material destruction, the spiral conveyor 2 of the reactor 1 has blades 19, which are installed at each turn of the spiral, and which allow intensifying the heat and mass transfer processes inside the reactor 1 by lifting the material upward, thereby increasing the residence time of the material in the reactor 1, which makes it possible to reduce its size (Fig. 2).

At the same time, our experiments showed that, all other things being equal, the same frequency of rotation of the spiral, the same mass of the processed material -5 kg, in the reactor 1 in the form of a pipe Dy80 1.5 m long, the processing of the material takes place in 12 minutes without blades 19 , and in 34 minutes with 19 shoulder blades.

A conical screw feeder with a spiral conveyor 23, made with the possibility of supplying crushed material of different morphological composition and moisture content, is used as a feeder 3 in a waste processing plant. This spiral conveyor 23 of the screw feeder 3 has turns 24, the diameter of which decreases from the inlet to the outlet of the conveyor 23 of the screw feeder 3 (Fig. 4).

This design of the feeder 3 makes it possible to provide a hermetic seal of the material in it when the crushed material is fed into it, which contributes to less penetration of odor from the reactor 1.

The tightness of the seal created in the feeder 3 is checked by an excess pressure of about 6 kg / cm ² at operating temperatures and modes.

The declared installation for waste processing operates as follows.

Pre-crushed waste material is fed into the loading chamber of a conical screw feeder 3 with a spiral conveyor 23, which is configured to supply crushed material of different morphological composition and moisture content. The spiral conveyor 23 of the screw feeder 3 has turns 24, the diameter of which decreases from the inlet to the outlet of the conveyor 23 of the screw feeder 3.

This design of the feeder 3 makes it possible to provide a hermetic seal in the feeder 3 when the crushed material is fed into it, which contributes to less penetration of odor from the reactor 1.

Further, along the spiral conveyor 23 of the feeder 3, the crushed material is fed into the first zone 20 of the material supply of the reactor 1 for low-temperature destruction, inside which the material begins to move due to the operation of the spiral conveyor 2.

After entering the second heating zone 21, the material begins to be heated using the installed heating jacket 17, placed around the reactor 1, with burners that are connected to the hydrocarbon gas extraction section 16 through the hydrocarbon gas pipeline 18, with the possibility of entering hydrocarbon gas into the burners for combustion and thereby heating the reactor 1. In this case, the spiral conveyor 2, in the material heating zone 21, is made with an increasing step "n" of the spiral turn. That is, if the spiral conveyor 2 has in the first zone 20 the standard pitch of the spiral turn "n", then in the second zone 21 the conveyor 2 will have the first pitch of the spiral turn of the size 1.1 "p", the second pitch of the spiral will have the size 1.2 "P", the third step will be 1.3 "p" and so on. Each new step of the turn of the spiral will increase by 10%. In this case, the standard step of the turn "n" of the spiral of the conveyor 2 is selected depending on the outer diameter "D" of the spiral of the conveyor 2 in accordance with the ratio: n <D (Fig. 3). This solution for the second heating zone 21 of the conveyor 2 avoids the formation of a blockage, since the material in this zone has the temperature is lower than the temperature of the beginning of its destruction, and with the same pitch of the spiral turn it is prone to compaction.

In the process of passing the material heating zone 21, flue gases are formed, which through the outlet 7 through the pipeline 8 exit through the chimney 9.

After heating to the required temperature of the beginning of its destruction, the material enters the third zone 22 of the reactor 1, in which the process of destruction (decomposition) of the material into a solid product (carbon residue) and a vapor-gas mixture begins. As a result of the destruction of the material, the solid product through the outlet 4 enters the installed means for unloading the solid product 5, connected to the receiving unit 6 of the spiral conveyor 2, and the vapor-gas mixture through the outlet 10 enters the pipeline 11, which is connected through the filter 12 to the rectification column 13 containing the section extraction of technical water 14, a section for the selection of liquid hydrocarbons 15, as well as a section for the selection of hydrocarbon gas 16. Hydrocarbon gas from the selection section 16 enters through the installed pipeline 18 into the heating jacket 17 of the reactor 1.

In addition, to intensify the heat and mass transfer processes along the entire length of the third zone 22 of material destruction, the spiral conveyor 2 is equipped with blades 19, which allow the material to be lifted upward, thereby increasing the residence time of the material in the reactor 1, which makes it possible to reduce its size.

Thus, in the waste processing plant, a significant increase in the efficiency of its operation is ensured, while simplifying its design due to the use of a spiral conveyor 2 with an increasing spiral pitch, as well as due to the presence of 2 blades 19 on the conveyor spiral for a more efficient intensification of the material inside the reactor 1. In addition, due to the presence of special turns 24 on the spiral conveyor 23 of the screw feeder 3, the diameter of which decreases from the inlet to the outlet of the feeder 3, it provides a hermetic seal of the material, which contributes to less penetration of odor from the reactor 1.

As will be apparent to those skilled in the art, the invention may be developed in other specific forms without departing from the spirit of the invention.

However, the present embodiments are to be considered merely illustrative and not limiting, with the scope of the invention represented by its claims, and is intended to include all possible modifications and scope of equivalence to the claims of the present invention.

Claims

CLAIM

1. Waste treatment plant containing

- a reactor for low-temperature destruction with a spiral conveyor, at the inlet of which a feeder is installed, and at the first outlet of the spiral conveyor, a means for unloading a solid product is installed, connected to the receiving unit of the spiral conveyor, while

- - the reactor has a second outlet for flue gas and a third outlet for the pipeline of the steam-gas mixture, which is connected to the rectification column, due to the fact that

- - the reactor has three zones,

- the first zone for feeding material into the reactor,

- the second heating zone of the material, and

- the third zone of destruction of the material, while

- - the spiral conveyor has a spiral with an increasing pitch of the spiral turn,

- the spiral of the spiral conveyor in the material destruction zone has blades mounted on the spiral turns and made with the possibility of providing, in addition to the linear movement of the material, its vertical movement.

2. Installation for waste processing according to claim 1, characterized in that the step "n" of the spiral of the conveyor is selected depending on the outer diameter "D" of the spiral of the conveyor in accordance with the ratio: n <D.

3. Installation for waste processing according to claim 1, characterized in that each subsequent step "n" of the conveyor spiral turn in the material heating zone in the reactor is increased by 10% from the previous step of the conveyor spiral.

4. Installation for waste processing according to claim 1, characterized in that a conical screw feeder with a spiral conveyor is used as a feeder, which is made with the possibility of feeding into it crushed material of different morphological composition and moisture content, and at the same time providing a hermetic seal in the feeder when feeding crushed material into it.

5. Installation for waste processing according to claim 4, characterized in that the spiral conveyor of the screw feeder has turns, the diameter of which decreases from the inlet to the outlet of the conveyor of the screw feeder.

6. Installation for waste processing according to claim 1, characterized in that it contains a filter located between the third outlet of the reactor and the pipeline of the steam-gas mixture.

7. Installation for waste processing according to claim 1, characterized in that the rectification column contains a section for the selection of technical water, a section for the selection of liquid hydrocarbons, and a section for the selection of hydrocarbon gas.

8. Installation for waste processing according to claim 7, characterized in that it contains a jacket with burners for heating the reactor, placed around the reactor, while the jacket with burners is connected to the hydrocarbon gas sampling section with the possibility of entering hydrocarbon gas into the burners for combustion and heating thereby the reactor.