RU91409U1 - INSTALLATION FOR THERMAL PROCESSING OF SOLID DOMESTIC WASTE - Google Patents

Abstract

A plant for the thermal processing of municipal solid waste, containing a receiving and unloading device, a waste incinerator sequentially located behind it, consisting of a feed hopper connected to a combustion chamber having an automatically operating burner for burning gaseous fuel, and heating tail surfaces, a two-stage gas treatment system, a boiler -utilizer, consisting of a device for reheating flue gases by burning gaseous fuel, the chamber and the tail surfaces of the heating EVA, in which there are air heaters with an air supply mechanism, a filter for trapping mercury vapor, located between the recovery boiler and the chimney, a melting compartment connected to the combustion chamber, characterized in that it is equipped with a device for cleaning the waste filtrate installed under the receiving an unloading device, devices for producing metal ingots and building materials from incineration waste associated with the melting department, a device for ultrafine grinding of the mixture for trapping mercury vapor associated with a filter for trapping mercury vapor and with a two-stage gas cleaning system, moreover, the discharge hopper of the incinerator is made with a safety mechanism designed for safe operation of the furnace, while the mechanism for supplying air to the air heaters is located directly at the recovery boiler, and the melting compartment connected to the combustion chamber of the incinerator and a two-stage gas treatment system.

Description

The proposed utility model relates to the field of solid waste processing using the fire method (power system), namely, to a plant for the thermal processing of municipal solid waste, and can be used both in public utilities and in industry.

A known installation for the thermal processing of solid waste, including a chamber furnace, consisting of a combustion chamber with a hopper for loading waste and an outlet for removing ash residue in the slag receiver and an afterburner communicated by the duct with a scrubber, and a gas filtration system with a dust storage bin. (G.P. Bespamyatnov et al. "Thermal methods for the neutralization of industrial waste", ed. "Chemistry", 1969, p.12, Fig. 4).

The disadvantages of the known device are:

- huge areas occupied by the components of the installation;

- in the slag receiver without heating, the slag hardens quickly and salts and oxides of heavy metals that get into it with an ash residue are not removed;

- the gas leaving the furnace is not neutralized and the harmful and toxic compounds present in it: metal vapors, dioxins, chlorides, furans, polyaromatic hydrocarbons - enter the atmosphere.

A device for burning household waste containing a receiving and unloading device, a successively located waste incinerator with a furnace, a combustion chamber and tail heating surfaces, a two-stage gas cleaning device, a waste heat boiler with a camera and tail heating surfaces and a chimney (RF Patent No. 2114357 , IPC F23G 5/00 dated 06/27/98).

However, the known device has a drawback, namely, the resulting significant amount of products of incomplete combustion of waste (chemical and mechanical combustion), affecting the formation of hazardous harmful substances such as dioxins (C ₁₂ H ₄ Cl ₄ O ₂ ) and furans (C ₁₂ H ₄ Cl ₄ O).

The closest in technical essence to the proposed technical solution is the installation for the thermal processing of municipal solid waste, containing a receiving and unloading device, a waste incinerator, sequentially located behind it, consisting of a feed hopper connected to a combustion chamber having an automatically operating burner for burning gaseous fuel, and tail heating surfaces, a two-stage gas cleaning system, a waste heat boiler, consisting of a device for re-heating the smoke gas emissions by burning gaseous fuel, a chamber and tail heating surfaces in which air heaters with an air supply mechanism are located, a filter for trapping mercury vapor located between the recovery boiler and the chimney, a melting compartment associated with the combustion chamber (see patent RF №2303746 according to Cl F23G 5/14, 2005).

The well-known installation allows you to completely burn solid, household waste, without the formation of hazardous harmful substances.

However, the known solution has several disadvantages, namely:

- there is no neutralization of the waste filtrate, consisting of harmful components obtained by the chemical reaction of waste with moisture;

- there is no protection of the incineration boiler in case of an emergency (for example, waste loading in the event of a furnace chamber malfunction);

- increased metal consumption of the installation due to complex connections between structural elements, for example, air supply from the receiving and unloading device to the air heaters of the recovery boiler;

The technical result solved by the proposed utility model is the creation of a plant design for the thermal processing of municipal solid waste, which allows for complete environmental safety and complete non-waste technological process of waste processing.

The technical result in the proposed utility model is achieved by creating a plant for the thermal processing of municipal solid waste, containing a receiving and unloading device, a waste incinerator sequentially located behind it, consisting of a feed hopper connected to a combustion chamber having an automatically operating burner for burning gaseous fuel, and tail heating surfaces, a two-stage gas cleaning system, a waste heat boiler, consisting of a device for reheating flue gases, s the combustion of gaseous fuel, the chamber and the tail surfaces of the heating, in which there are air heaters with an air supply mechanism, a filter for trapping mercury vapor located between the recovery boiler and the chimney, a melting compartment connected to the combustion chamber, which, according to the utility model, is provided a device for cleaning waste filtrate, installed under the receiving and unloading device, devices for receiving metal ingots and building materials from waste from waste, with a melting compartment, a device for ultrafine grinding of the mixture for trapping mercury vapor associated with a filter for trapping mercury vapor and with a two-stage gas purification system, moreover, the feed hopper of the incinerator is made with a safety mechanism designed for safe operation of the furnace, while the air inlet mechanism air heaters are located directly at the recovery boiler, and the melting compartment is connected to the combustion chamber of the incineration boiler and a two-stage gas cleaning system.

Providing the installation with a device for cleaning the filtrate of waste, installed under the receiving and unloading device allows you to clean the filtrate from harmful substances and get clean process water, which is returned to the technical cycle of the enterprise.

Providing the installation with devices for the production of metal ingots and building materials from waste combustion expands the functionality of the installation.

The installation of the device for ultrafine grinding of the mixture for trapping mercury vapor can significantly increase the degree of purification of gases from mercury vapor, in addition, the introduction of an ultrafine mixture in a two-stage gas purification system provides additional purification from mercury vapor.

The location of the mechanism for supplying air to the air heaters directly at the recovery boiler (room temperature air intake) simplifies the design of the installation, reduces its metal consumption by eliminating significantly the number of pipelines, and saves energy by using warmer air.

Patent studies have shown that technical solutions with the indicated set of essential features are not known in similar installations for the thermal processing of municipal solid waste, i.e. the proposed solution meets the criterion of "novelty."

We believe that the information set forth in the application materials is sufficient for the practical implementation of the invention.

The essence of the proposed installation for the thermal processing of municipal solid waste is illustrated by the following description and drawing, which shows the technological scheme of the proposed installation.

The installation for the thermal processing of municipal solid waste contains a receiving and unloading device 1, a waste incineration boiler sequentially located behind it, consisting of a feed hopper 2 with a safety mechanism 3, designed for safe operation of the furnace, and connected to the furnace chamber 4, which has an automatically operating burner 5 for burning gaseous fuels, and tail surfaces for heating 6, a two-stage gas treatment system 7, a waste heat boiler 8, consisting of a device for reheating fumes gas 9, due to the combustion of gaseous fuel, the chamber 10 and the tail heating surfaces 11, in which the air heaters 12 with the air supply mechanism 13 are located, a filter 14 for trapping mercury vapor, located between the waste heat boiler 8 and the chimney 15, the melting compartment 16 associated with the combustion chamber 4, a device for cleaning waste filtrate 17, installed under the receiving and unloading device 1, a device for producing metal ingots 18 and building materials from incineration waste 19 associated with smelting department 16, a device for ultrafine grinding of a mixture for trapping mercury vapor 20, connected to a filter 14 for trapping mercury vapor and with a two-stage gas purification system 7.

The two-stage gas cleaning system 7 may consist of a device for cleaning coarse dust and a filter for cleaning fine dust and chemical cleaning of gases.

The mechanism for supplying air 13 to the air heaters 12, for example, a fan, is located directly at the recovery boiler 8, and the melting compartment 16 is connected to the combustion chamber 4 of the incinerator and a two-stage gas cleaning system 7.

In the upper part of the receiving and unloading device 1, a clamshell overhead crane 21 is placed, which ensures the loading of solid waste by the supply hopper 2 of the incinerator.

In the waste incineration boiler and in the waste heat boiler 8 in one of the flues, an ammonia solution input system 22 is provided to neutralize NO _x .

To generate electricity, a turbine generator 23 is provided in the installation, which receives a pair of necessary parameters from the waste incineration boiler and the recovery boiler 8.

Installation for the thermal processing of municipal solid waste works as follows:

Municipal solid waste is stored in the receiving and unloading device 1.

Using a device for cleaning the waste filtrate, installed under the receiving and unloading device, the waste filtrate is cleaned of harmful substances and the resulting clean process water is returned to the enterprise’s technical cycle.

The device used can be of any known design that allows you to clean such products, and the authors do not claim its novelty.

With the help of a clamshell overhead crane 21, the garbage enters the feed hopper 2 of the incinerator, then into the combustion chamber 4 where the products of incomplete combustion of waste products are burned and partially burned and the molecular bonds of primary dioxins and furans are destroyed.

The operations of burning garbage and partial afterburning of products of incomplete combustion of waste are known and the authors do not claim to be new.

The temperature of the incineration is selected depending on the technological capabilities and the requirements for the final product.

From the incinerator, the flue gases are sent to a two-stage gas cleaning system 7, where they are cleaned of mechanical suspended matter, sulfur oxides, hydrogen fluoride and hydrogen chloride and these carbides, as well as heavy metals, which are harmful substances.

After the gas treatment system 7, the flue gases enter the device for reheating the flue gases 9 of the recovery boiler 8, where the products of incomplete combustion of the waste are completely burned out.

Then these heated flue gases enter the chamber 10 of the recovery boiler 8, where the final destruction of the molecular bonds of secondary dioxins and furans formed in the recovery zone of the incinerator takes place.

A recovery boiler 8 operating on fossil fuels (for example, gaseous) allows producing a constant amount of steam together with the incinerator boiler 8, which is used in the turbogenerator 23 and generates electricity, as well as to reliably provide thermal energy to its own and external consumers.

The waste heat boiler 8 receives flue gases from the incinerator, purified from sulfur oxides, fluoride and hydrogen chloride, which are very corrosive substances, then they enter the air heaters 12 with air supply mechanism 13 installed in the tail surfaces of the heating 11.

Since the air supply mechanisms, for example, fans (the amount that depends on the process conditions) are installed directly near the waste heat boiler 8, the temperature of the supplied air is much higher than in the prototype, which reduces the energy costs of the installation.

Before the exhaust flue gas enters the chimney 15, a filter 14 is installed for trapping mercury vapor, which is part of the original household waste. Moreover, the filter is filled with a mixture for trapping vapors of ultrafine grinding mercury, for example, activated carbon and calcium oxide (quicklime).

The mixture is also added to the gas treatment system. The fineness of the mixture allows for a greater degree of purification of gases from mercury.

For the afterburning of products of incomplete combustion contained in the resulting slag, use the melting compartment 16, in which the slag is converted into a liquid state. In it, caught fly ash is melted. Then all of the specified mineral part is used for the manufacture of marketable products.

To ensure stabilization of the process of burning solid household waste, and to maintain the required temperature in both boilers, as well as for the operation of the recovery boiler as part of the proposed technological scheme, fossil fuels (for example, gaseous) are used.

A pilot plant was manufactured and the following results were obtained:

No. Estimated performance Indicator value one Installed garbage processing capacity 100 thousand tons / year 2 Installed electric power generation 12 MW 3 The number of employees 20 pax four Power consumed for own needs 2.5 MW 5 Estimated amount of required external fuel (standard fuel, q = 7000 kcal / m3) 1.5 million cubic meters / year 6 Estimated amount of metal recovered from the garbage 4-8% 7 Estimated amount of building materials produced (including gravel) 25% 8 Electricity supply to external consumers (in operating mode) ~ 9 MW 9 Estimated payback period of the project up to 5 years 10 Estimated number of population serviced by the MSW processing station * (* - at the rate of 400 kg of MSW1 people per year) 100 thousand people

Claims (1)

A plant for the thermal processing of municipal solid waste, containing a receiving and unloading device, a waste incinerator sequentially located behind it, consisting of a feed hopper connected to a combustion chamber having an automatically operating burner for burning gaseous fuel, and heating tail surfaces, a two-stage gas treatment system, a boiler -utilizer, consisting of a device for reheating flue gases by burning gaseous fuel, the chamber and the tail surfaces of the heating EVA, in which there are air heaters with an air supply mechanism, a filter for trapping mercury vapor, located between the recovery boiler and the chimney, a melting compartment connected to the combustion chamber, characterized in that it is equipped with a device for cleaning the waste filtrate installed under the receiving an unloading device, devices for producing metal ingots and building materials from incineration waste associated with the melting department, a device for ultrafine grinding of the mixture for trapping mercury vapor associated with a filter for trapping mercury vapor and with a two-stage gas cleaning system, moreover, the discharge hopper of the incinerator is made with a safety mechanism designed for safe operation of the furnace, while the mechanism for supplying air to the air heaters is located directly at the recovery boiler, and the melting compartment connected to the combustion chamber of the incinerator and a two-stage gas treatment system.