RU50635U1 - WASTE MANAGEMENT PLANT - Google Patents

Abstract

The utility model relates to the field of disposal of wastes containing organic matter in public utilities and industry through their thermal processing under conditions that provide an environmentally friendly composition of the final products - flue gases and coke oven residue. The technical problem to be solved: creation of conditions that exclude the possibility of formation of thermal decomposition in the chamber during pyrolysis of waste explosive concentrations of gas-vapor mixture and increase in plant productivity. The waste disposal installation comprises a thermoreactor, a vertical cyclone furnace with a afterburner, equipped with a burner in the upper part, a heating chamber with a thermal decomposition chamber, equipped with means for loading wastes and unloading coke residue and a mixing device, a catalytic afterburner, a heat exchanger, and a gas purification system , smoke exhaust and chimney. The gas duct between the heating chamber and the heat exchanger is equipped with a steam generator connected to the superheater located in the heating chamber and connected to the input to the steam distribution device located in the thermal decomposition chamber.

Description

The utility model relates to the field of waste disposal in utilities and industry through their thermal processing in conditions that provide an environmentally friendly composition of the final products - flue gases and coke oven residue.

The waste disposal installation comprises a thermoreactor, a vertical cyclone furnace with a afterburner, equipped with a burner in the upper part, a heating chamber with a thermal decomposition chamber, equipped with means for loading wastes and unloading coke residue and a mixing device, a catalytic afterburner, a heat exchanger, and a gas purification system , smoke exhaust and chimney. The gas duct between the heating chamber and the heat exchanger is equipped with a steam generator connected to the superheater located in the heating chamber and connected to the input to the steam distribution device located in the thermal decomposition chamber.

A device for the disposal of solid waste containing a vertical gasification chamber, means for feeding waste and unloading ash residue, a vertical pipe for withdrawing gaseous products located inside the gasification chamber, means for supplying a gasification agent to the gasification chamber and a heating chamber with means for outside the gasification chamber supply of fuel, air and output of combustion products / 1 /. However, this device does not provide effective mixing of the waste and uniform heat transfer along the entire height of the column of pyrolyzable material and unsorted waste cannot be processed, since it is not possible to unload large inclusions (stones, glass, banks, etc.) remaining in the ash residue after complete gasification of the waste.

Closest to the claimed utility model for the design of the main equipment, the principle of operation and the achieved result is a solid waste disposal plant containing a thermoreactor, a catalytic afterburner, a heat exchanger, a gas treatment system, a smoke exhauster and a chimney. The thermoreactor contains a gas distribution device, a vertical cyclone furnace equipped with a burner in the upper part, a afterburner, a heating chamber with a grate installed in it, an ash residue removal system and a thermal decomposition chamber equipped with means for

loading waste and unloading coke residue and a mixing device with mobile working bodies, / 2 /.

The disadvantage of this device is that, since the whole process is carried out under the vacuum created by the smoke exhauster located at the outlet of the installation, there is a constant danger of getting into the chamber thermal decomposition of atmospheric air due to suction, as well as when loading waste, which may result in the formation of explosive mixture of pyrolysis gases with air. At the same time, the operation of the mixing device creates a suspension of fine dust in the chamber volume containing smoldering particles that are sources of ignition. The combination of these factors can lead to rapid ignition (explosion) in the thermal decomposition chamber.

This utility model is intended for the safe thermal destruction of organo-containing solid waste by creating conditions that prevent the formation of an explosive mixture of gases with air by supplying the required amount of water vapor to the thermal decomposition chamber.

The specified technical result is achieved due to the fact that the gas duct between the heating chamber and the heat exchanger is equipped with a steam generator connected to the superheater located in the heating chamber and connected to the input to the steam distribution device located in the thermal decomposition chamber.

Supply of a gas duct having a temperature of 600-700 ° C with a steam generator allows to obtain the required amount of water vapor with a temperature of 150-200 ° C.

Placing a superheater in a heating chamber having a temperature of 800-900 ° C allows it to overheat the water vapor entering it from the steam generator to a temperature of 600-700 ° C, corresponding to the operating temperature of the thermal decomposition chamber.

The supply of the thermal decomposition chamber with a steam distribution device allows evenly distributing water vapor throughout the internal volume of the chamber, creating the necessary explosion-proof concentration of the vapor-gas mixture in it.

The utility model is illustrated by the drawing of figure 1, which shows a longitudinal section of a plant for processing solid waste.

The installation for processing solid waste contains a thermoreactor-1, a vertical cyclone furnace with a afterburner-2, equipped with a burner-3 in the upper part, a heating chamber-4 with a thermal decomposition chamber-5, equipped with means for loading waste-6 and unloading coke residue-7 and mixing device-8, catalytic afterburner-9, heat exchanger-10, gas purification system-11, smoke exhauster-12 and chimney-13. The gas duct-14 between the heating chamber and the heat exchanger is equipped with a steam generator-15,

connected to the superheater-16, located in the heating chamber and connected to the input to the steam distribution device-17, located in the thermal decomposition chamber. The gas duct-14 is equipped with a gas distribution device-18.

Installation works as follows:

Turn on the burner-3. The flue gases generated during the combustion of the fuel in the burner heat the cyclone firebox-2 and are discharged into the heating chamber-4, where the thermal decomposition chamber-5 is heated and through the gas duct-14, catalytic afterburner-9, heat exchanger-10, gas-cleaning system-11, and smoke exhaust- 12 and chimney-13 are discharged into the atmosphere.

Steam is supplied to steam generator-15, which evaporates, in the form of steam with a temperature of 150-200 ° C, enters the superheater-16 from where the steam, superheated to a temperature of 600-700 ° C, enters the steam distributor-17 located in the thermal decomposition chamber-5 .

About one cubic meter of steam is formed from one kilogram of water at a temperature of 650 ° C. In a real device, the flow rate of even several kilograms of water provides multiple flushing with steam of the entire volume of the thermal decomposition chamber, thereby preventing the formation of an explosive mixture of gases with air.

In the chamber of thermal decomposition through the means of loading-6 load the feedstock-waste containing organic matter.

Warming up, the waste is initially dried and then, as it warms up, gaseous thermal decomposition products (pyrogas) begin to be released from them, which are tangentially fed to the upper part of the cyclone furnace-2. At the same time, heated air enters the same place. The gas-air mixture ignites from the torch of the burner and burns in a rotating gas stream, which, due to high turbulence, high relative speeds and residence time, provides high-quality combustion of combustible components of low-calorie gases and solid decomposition products together with the fuel necessary to maintain the process.

Gaseous products of combustion, depending on the specified mode and position of the valves of the gas distribution device-18, enter the gas duct-14 either from the heating chamber-4 or from the afterburner of the cyclone furnace-2 and then enter the catalytic afterburner-8.

In the catalytic afterburner, carbon monoxide and residual concentrations of organic components are burned in the full oxidation mode, which prevents secondary reactions from occurring.

After the catalytic afterburner, the flue gases enter the heat exchanger-10 and then, after the integrated gas purification system-11, the exhaust fan-12 through the pipe-13 is released into the atmosphere.

The presence in the process of water vapor at a temperature of 600-700 ° C also contributes to the gasification of carbon contained in the waste, which increases the rate of thermal decomposition and thereby increases the productivity of the installation.

Thus, the combination of these essential features provides the possibility of environmentally friendly, safe thermal destruction of organo-waste by creating conditions that prevent the formation of an explosive mixture of gases with air and increases the productivity of the installation due to gasification of the carbon component of the waste.

Information sources:

1. US patent No. 4224286, CL. From 01 to 31/08, 1980.

2. RF patent No. 42289 "Installation for the disposal of solid waste"

Claims (1)

A waste utilization installation comprising a thermoreactor, a vertical cyclone furnace with an afterburner equipped with a burner in the upper part, a heating chamber with a thermal decomposition chamber provided with means for loading wastes and unloading the coke residue and a mixing device, a catalytic afterburner, heat exchanger, system gas purification, smoke exhaust and chimney, characterized in that the gas duct between the heating chamber and the heat exchanger is equipped with a steam generator connected to the steam a heater placed in the heating chamber and connected to the input to the steam distribution device located in the thermal decomposition chamber.