RU2741936C1 - Method and device for co-combustion of wastes and semi-dry waste sludge - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to method and device for co-combustion of wastes and semi-dry waste sludge. Proposed device comprises furnace, grate in furnace, distributing unit of wastes made with possibility to distribute wastes along said grate, and distributing unit of wet (semi-dry) waste sludge, made with possibility to transport wet waste sludge to rear arch of furnace and to load it into furnace. Outlet of gaseous combustion products of furnace is connected with waste heat boiler, deoxidizing column and sleeve filter in series through pipeline, so that, passing through recovery boiler, deoxidizer column and sleeve filter, gaseous combustion products through induced exhaust fan get into exhaust pipe and enter atmosphere. Water in the heat recovery boiler is heated to such a degree as to produce steam capable of driving the turbine generator with generation of electric energy. There is a screw conveyor configured to transport wet waste sludge from the waste sludge bunk to the furnace rear arch so that the wet waste sludge is scattered along the grate in the furnace due to gravity.

EFFECT: in the process of combined burning of wastes and semi-dry waste sludge, the device can convert heat energy into electric energy and enables to use waste sludge as a useful resource.

6 cl, 1 dwg

Description

The technical field to which the present invention relates

The present invention relates to waste incineration, in particular, to a method and device for co-incineration of waste and semi-dry waste sludge.

Background of the invention

In recent years, there has been rapid urban growth in China. If we extrapolate the current rate of urbanization in China, based on the fact that in 2010 the amount of municipal solid waste in China reached 264 million tons, then in 2030 it should reach 409 million tons, and in 2050 - 528 million tons, which indicates a rapid an increase in the amount of solid urban waste. In cities, there are 440 kg of household waste per capita per year, so the total annual volume exceeds 160 million tons, which is more than a quarter of the world's waste. This number is growing by eight to ten percent every year, resulting in serious environmental pollution. Landfill, composting and incineration with energy generation are traditional technologies for solid waste treatment. Burial has found wide application due to low costs, proven technology and ease of management. However, before disposal, the waste is not neutralized, and bacteria and viruses remain in huge quantities. In addition, landfill leachate (liquid that has seeped through the solid mass of waste and contains any substances in dissolved or solid form) pollutes the soil and groundwater, which directly threatens the nature and human health. Incineration of waste for energy production is attracting a lot of attention and, due to such advantages as complete recycling, significant reduction in capacity, short recycling time, no need for large areas and the possibility of obtaining thermal energy, this technology is rapidly developing. As of February 2016, there were 231 waste incinerators in operation in China.

On the other hand, with the acceleration of urbanization and industrialization in China, the volume of sewage sludge has increased significantly, which threatens to seriously pollute the environment if not properly recycled. Incineration of waste sludge could remove all water and organic matter, as well as pathogens from it, minimize its volume and reduce the release of pollutants, that is, it would be an effective way to treat waste sludge. Household waste and its calorific value have grown rapidly in recent years. Incineration of waste can provide sufficient heat to incinerate waste sludge. According to the relevant administrative orders, cities that have or plan to build power plants operating on the incineration of household waste must ensure the co-incineration of sewage sludge and household waste, which allows not only to use existing equipment for incineration and purification of waste gases in installations waste incineration, but also reduce investment and operating costs. Co-incineration of sewage sludge and household waste to obtain energy achieves the goal formulated as "volume reduction, stabilization, neutralization" in the processing of sewage sludge and shows a good economic effect.

Brief description of the invention

The aim of the present invention is to overcome the disadvantages of the prior art and to provide a method and device for co-incineration of waste and semi-dry waste sludge, which would achieve the goal formulated as "volume reduction, stabilization, neutralization" when processing waste sludge.

The purpose of the invention is achieved by the following technical solution.

The proposed device for co-incineration of waste and semi-dry waste sludge contains a furnace, a grate 6 in the furnace, a waste distribution unit configured to distribute waste over said grate 6, and a wet waste sludge distribution unit configured to transport wet waste sludge to the rear arch of the furnace and load this wet sewage sludge into the furnace, while

the outlet of the gaseous combustion products of the furnace is connected to the waste heat boiler 8, the deoxidizer column 12 and the bag filter 16 in series through the pipeline, so that passing in the furnace through the waste heat boiler 8, the deoxidizer column 12 and the bag filter 16, the gaseous combustion products through the induced the exhaust fan 17 entered the exhaust pipe and exited into the atmosphere,

the waste heat boiler 8 is connected to the turbo generator 11 so that the water in the waste heat boiler 8 is heated to such an extent as to produce steam capable of driving the turbine generator 11 to generate electrical power, and

The distribution unit of wet sewage sludge contains a sewage sludge hopper 10 and a screw conveyor 9 configured to transport wet sewage sludge from said hopper 10 to the rear roof of the furnace, so that wet sewage sludge is dispersed along the grate 6 in the furnace due to gravity.

At the entrance to the furnace, an auxiliary fan 5 is installed, made with the ability to supply external air to the furnace in order to facilitate the afterburning of gas that has not been completely burnt in the furnace, so that the gaseous combustion products are carried away by the backflow turbulence created by the auxiliary fan 5 and the residence time of these gaseous combustion products in the area of the exit from the furnace at a temperature of 850 ° C - 900 ° C, and

the grate 6 contains, in order from top to bottom, drying section A, pyrolysis section B, fixed carbon-combustion section C and fixed carbon-exhaust section D.

The deoxidizing column 12 is also connected to the lime feed hopper 14, and the pipeline between the deoxidizing column 12 and the bag filter 16 is also connected to the activated carbon feed hopper 15.

The waste distribution unit contains a waste bunker 2 and a gripper 3, made with the ability to capture waste in the waste bin 2 and feed them into a hopper, so that waste falls from this hopper onto the grate 6 in the furnace, so that

Fly ash under the waste heat boiler 8, the deoxidizer column 12 and the bag filter 16 was collected in the fly ash bin 13.

To ensure sufficient combustion of waste in the furnace under the grate 6, a blower 7 is located, configured to supply air to the furnace, to collect the landfill filtrate under the waste bin 2, a reservoir 1 is installed, configured to collect the liquid present in the waste, and to collect slag below the grate 6 slag collection tank installed 4.

The proposed method of co-incineration of waste and semi-dry waste sludge contains the following operations:

the waste in the hopper is moved to the grate 6; wet sewage sludge, located in the sewage sludge bunker 10, is transported by means of a screw conveyor 9 to the rear roof of the furnace, where the wet sewage sludge is distributed over the grate 6 in the furnace due to gravity,

due to the primary wind and heat radiation of the furnace on the grate, four incineration processes are carried out: drying, pyrolysis, fixed carbon combustion and fixed carbon evacuation in waste and wet sewage sludge; the high-temperature gaseous combustion products obtained in the waste incineration process are introduced into the waste heat boiler 8, heating the water in the waste heat boiler 8 in order to generate steam for driving the turbine generator 11, and

to carry out the neutralization reaction, the gaseous combustion products discharged from the waste heat boiler 8 are introduced into the deoxidizer column 12, where these gaseous combustion products come into contact with the slaked lime particles in the lime feed hopper 14; for the adsorption of particles contained in gaseous combustion products, combustion gases are passed through activated carbon located in the activated carbon feed hopper 15, after which, for separation, the combustion gases contained in the combustion gases of particles and reagents are passed through a bag filter 16, and finally with the help of an induced of the exhaust fan 17, combustion gases are introduced into the exhaust pipe through which they are released into the atmosphere.

The proposed invention has the following advantages over the prior art.

(1) The present invention is aimed at efficient and low-toxic incineration of waste and sewage sludge and the clean use of heat, achieving the goal formulated as "reduction, stabilization and harmlessness". Semi-dry sewage sludge, temporarily stored in a sewage sludge bin, is loaded into the furnace using a wet sewage sludge distribution unit. The high temperature combustion gases dry the wet (semi-dry) sewage sludge loaded into the furnace, which is then incinerated together with the waste, as a result of which all pathogenic microorganisms are destroyed, the volume of sewage sludge is minimized and polluting emissions are reduced. A waste incineration power generation system can fully recycle the combustion gases, and the combustion gases from the incineration of sludge can also be recycled, thereby reducing investment and operating costs.

(2) When processing semi-dry waste sludge in the waste incineration process, the heat generated can be used to generate electricity, which allows the waste sludge to be used as a useful resource. Gaseous combustion products leaving the waste heat boiler enter the deoxidizer column, come into contact with the slaked lime particles in the slaked lime supply tank, as a result of which a neutralization reaction takes place. Then these gaseous combustion products are passed through the activated carbon contained in the activated carbon feed hopper, where the particles contained in the gaseous combustion products are adsorbed, and then through a bag filter to separate the particles and reagents in the combustion gases, and finally with the help of of the induced exhaust fan, combustion gases are introduced into the exhaust pipe through which they are released into the atmosphere.

(3) The slag resulting from the incineration of waste can be used as a raw material for building materials such as cement, brick and concrete, which serves to protect nature and, again, allows the use of waste sludge as a useful resource.

Thus, the technical solutions disclosed by the present invention are simple and easy to implement, favorable from the point of view of environmental protection, and highly economical. The proposed invention can find wide application for the processing of industrial and household waste urban and waste sludge incineration and has great application prospects.

Brief description of the attached graphics

The figure in the form of a structural block diagram shows the proposed device for co-incineration of waste and semi-dry waste sludge.

Detailed description of embodiments of the present invention

Next, the invention will be described in more detail on specific examples of its implementation.

As can be seen in the figure, the proposed device for co-incineration of waste and semi-dry waste sludge contains a furnace, a grate 6 in the furnace, a waste distribution unit configured to distribute waste over said grate 6, and a wet waste sludge distribution unit configured to transport wet (semi-dry) sewage sludge to the rear roof of the furnace and load this wet sewage sludge into the furnace, while

the outlet of the gaseous combustion products of the furnace is connected to the waste heat boiler 8, the deoxidizer column 12 and the bag filter 16 in series through the pipeline; passing in the furnace through the waste heat boiler 8, the deoxidizing column 12 and the bag filter 16, the gaseous combustion products through the induced exhaust fan 17 enter the exhaust pipe and are released into the atmosphere,

waste heat boiler 8 is connected to a turbine generator 11; the water in the waste heat boiler 8 is heated to such an extent as to produce steam capable of driving the turbine generator 11 to generate electrical power, and

The distribution unit of wet sewage sludge contains a sewage sludge hopper 10 and a screw conveyor 9 configured to transport wet sewage sludge from said hopper 10 to the rear roof of the furnace, so that wet sewage sludge is dispersed along the grate 6 in the furnace due to gravity.

At the entrance to the furnace, an auxiliary fan 5 is installed, made with the ability to supply outside air to the furnace in order to facilitate the afterburning of gas that has not completely burned out in the furnace; the combustion gases are carried away by the backflow turbulence created by the auxiliary fan 5, thereby prolonging the residence time of these combustion gases in the area of the furnace outlet at a temperature of 850 ° C - 900 ° C, and

the grate 6 contains, in order from top to bottom, drying section A, pyrolysis section B, fixed carbon-combustion section C and fixed carbon-exhaust section D.

High-temperature combustion gases in the furnace additionally dry wet (semi-dry) waste sludge when the latter is loaded into the furnace. This wet sewage sludge enters the drying section A, so that conditions are created for the co-incineration of semi-dry sewage sludge and waste.

The deoxidizing column 12 is also connected to the lime feed hopper 14, and the pipeline between the deoxidizing column 12 and the bag filter 16 is also connected to the activated carbon feed hopper 15.

The waste distribution unit contains a waste bunker 2 and a gripper 3 configured to capture waste in the waste bin 2 and feed them into a hopper, so that waste falls from this hopper onto the grate 6 in the furnace, while fly ash is under waste heat boiler 8, deoxidizer column 12 and bag filter 16 are collected in fly ash hopper 13. This fly ash can be used as a raw material for building materials.

A blower 7 is located under the grate 6, made with the ability to supply air to the furnace in order to ensure sufficient combustion of waste in the furnace, under the waste hopper 2 there is a reservoir 1 for collecting the landfill filtrate, made with the ability to collect the liquid present in the waste, and below the grate 6 there is a slag receiving tank 4. Slag can also be used as a raw material for building materials.

The proposed method of co-incineration of waste and semi-dry waste sludge contains the following operations:

the waste in the hopper is moved to the grate 6; wet sewage sludge, which is in the sewage sludge bunker 10, is transported by means of a screw conveyor 9 to the rear roof of the furnace, where wet sewage sludge is dispersed along the grate 6 in the furnace due to gravity,

due to the primary wind and heat radiation of the furnace on the grate, four incineration processes are carried out: drying, pyrolysis, fixed carbon combustion and fixed carbon evacuation in waste and wet sewage sludge; the high-temperature gaseous combustion products obtained in the waste incineration process are introduced into the waste heat boiler 8, heating the water in the waste heat boiler 8 in order to generate steam for driving the turbine generator 11, and

the combustion gases discharged from the waste heat boiler 8 are introduced into the deoxidizer column 12, where these combustion gases come into contact with the slaked lime particles in the lime feed hopper 14 to carry out the neutralization reaction; The gaseous combustion products are passed through the activated carbon located in the activated carbon feed hopper 15 to adsorb the particles contained in the combustion gases, after which the combustion gases are passed through the bag filter 16 in order to separate the particles and reagents present in the combustion gases, and finally, by means of an induced exhaust fan 17, the combustion gases are introduced into the exhaust pipe through which they are released to the atmosphere.

As stated above, the invention can be implemented in a better way.

The embodiments of the present invention are not limited to the above examples. Any other changes, modifications, substitutions, combinations and simplifications that do not violate the spirit and principle of the invention, should be considered equivalent variants and covered by its scope.

Claims (14)

1. A device for co-incineration of waste and semi-dry sewage sludge, characterized in that it contains a furnace, a grate (6) in the furnace, a waste distribution unit configured to distribute waste over said grate (6), and a wet waste sludge distribution unit, made with the ability to transport wet sewage sludge to the rear roof of the furnace and load this wet sewage sludge into the furnace, while the outlet of gaseous combustion products of the furnace is connected to a waste heat boiler (8), a deoxidizer column (12) and a bag filter (16) in series through a pipeline to ensure combustion of those passing through the waste heat boiler (8), a deoxidizer column (12 ) and a bag filter (16) of gaseous combustion products and their ingress through the induced exhaust fan 17 into the exhaust pipe and out into the atmosphere, while the waste heat boiler (8) is connected to the turbo generator (11) to provide, when heating water in the waste heat boiler (8), the possibility of generating steam capable of driving the turbine generator (11) to generate electrical energy, and a distribution unit for wet waste sludge, containing a waste sludge hopper (10) and a screw conveyor (9), made with the ability to transport wet waste sludge from the said bunker (10) to the rear roof of the furnace, ensuring the dispersion of wet waste sludge was dispersed along the grate (6) into furnace due to gravity. 2. The device according to claim. 1, characterized in that an auxiliary fan (5) is installed at the entrance to the furnace, made with the ability to supply external air to the furnace in order to facilitate the afterburning of the gas not completely burned in the furnace, ensuring the capture of gaseous combustion products created an auxiliary fan (5) with reverse flow turbulence in order to extend the residence time of these gaseous combustion products in the area of the exit from the furnace at a temperature of 850-900 ° C, while said grate (6) comprises a top-down drying section (A), a pyrolysis section (B), a fixed carbon-burning section (C) and a fixed carbon-evacuating section (D). 3. A device according to claim 2, characterized in that the deoxidizer column (12) is also connected to the lime feed hopper (14), and the pipeline between the deoxidizer column (12) and the bag filter (16) is also connected to the feed hopper (15 ) activated carbon. 4. A device according to claim 3, characterized in that the waste distribution unit comprises a waste bin (2) and a gripper (3) configured to capture waste in said waste bin (2) and feed them into a hopper with ensuring that waste from this hopper falls onto the grate (6) in the firebox, and Fly ash under the recovery boiler (8), the deoxidizer column (12) and the bag filter (16) was collected in the fly ash hopper (13). 5. The device according to claim. 4, characterized in that to ensure sufficient combustion of waste in the furnace under the grate (6) there is a blower (7) configured to supply air to the furnace, while collecting the landfill leachate under the waste bin (2) a tank (1) is installed, made with the ability to collect the liquid present in the waste, and a slag receiving tank (4) is installed to collect slag below the grate (6). 6. The method of co-incineration of waste and sewage sludge using the device according to claim 5, characterized in that it contains the following operations: the waste in the hopper is moved to the grate (6), the wet sewage sludge in the sewage sludge hopper (10) is transported using the screw conveyor (9) to the rear roof of the furnace, where they ensure the dispersion of wet sewage sludge along the grate (6 ) in the furnace due to gravity, due to the primary wind and heat radiation of the furnace, four incineration processes are carried out on the grate: drying, pyrolysis, fixed carbon combustion and fixed carbon outgassing in waste and wet waste sludge, and the high-temperature combustion gases obtained in the waste incineration process are introduced into the waste heat boiler (8), heating water in the waste heat boiler (8) in order to obtain steam for driving the turbine generator (11), and to carry out the neutralization reaction, gaseous combustion products discharged from the waste heat boiler (8) are introduced into the deoxidizer column (12), where these gaseous combustion products come into contact with the slaked lime particles in the lime feed hopper (14), while for the adsorption of particles contained in the gaseous combustion products, the gaseous combustion products are passed through activated carbon located in the activated carbon feed hopper (15), then, to separate the particles and reagents in the gaseous combustion products, the combustion gases are passed through a bag filter (16), after which By means of an induced exhaust fan (17), combustion gases are introduced into the exhaust pipe, through which they are released into the atmosphere.

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