RU196603U1 - INSTALLATION OF SOLID WASTE DISPOSAL - Google Patents

Abstract

The utility model increases the efficiency of the installation. A solid waste recycling installation containing a thermoreactor in which there is a thermal decomposition chamber equipped with a loading device, a coke ash residue discharge hatch and a agitator, the thermal decomposition chamber is placed in a heating chamber, the walls of which are covered with heat-insulating material, in the lower part of the heating the chamber has a grate for burning out the coke ash residue, and a burner located under the thermal decomposition chamber heating, a vertical cyclone furnace with an afterburner adjoins the end of the thermoreactor, in the upper part of which there is a burner for burning pyrolysis products, the unit is also equipped with a bypass duct to protect the thermal decomposition chamber from overheating, a flue gas flow distributor, a catalytic afterburner of organic compounds in flue gases, a heat exchanger with a fan, a cyclone, a scrubber for liquid purification of flue gases from solid inclusions, a fan-smoke exhauster, which ensures the installation of the air necessary for the combustion of the gas-vapor mixture, and the removal of flue gases into the pipe, by the control panel, the service platform, between the loading device and the thermal decomposition chamber there is an additional waste preheating chamber formed by fixed vertical walls and movable horizontal valves, the upper valve being hermetically sealed separates the preheating chamber from the receiving hopper of the loading device and the environment, and the lower valve from the kame Thermal decomposition, the walls of the preheating chamber, as well as both valves are coated with heat insulating material. The additional chamber for preheating the waste is equipped with agitators connected by mechanical gears with the agitator of the thermal decomposition chamber. The mixing of the waste in the additional preheating chamber with agitators ensures uniform heating and drying the total volume of waste in this chamber, which, when loading the waste into the thermal decomposition chamber, provides eryvny pyrolysis process and increases the efficiency of the installation.

Description

The utility model relates to equipment for environmentally friendly thermal destruction of solid industrial and household waste containing organic compounds.

A known installation for heat treatment and destruction of waste, consisting of a body lined with refractory material, inside of which there is a flue gas afterburner with a burner device and a waste burning chamber with a burner device, as well as a channel for passage of pyrolysis and flue gases from the combustion chamber to the afterburner, a flue gas removal channel from the afterburner and waste loading and sludge disposal devices. The waste loading device is located above the incineration chamber in the upper part of the installation housing and is made in the form of a lock loading chamber with a moving hatch and a closing door [1].

The disadvantage of the installation is its low efficiency.

In the process, the waste is constantly loaded through an open door into the lock chamber, then the door is closed, the hatch is shifted and the waste is dumped into the combustion chamber. This operation of the installation leads to significant heat loss when loading waste into the airlock through an open door. The discharge of a portion of cold and wet waste into the combustion chamber of the installation leads to a sharp decrease in the operating temperature and interruption of the working process for the time required for heating and drying the waste in the chamber.

There is also known a solid waste utilization installation containing a thermoreactor, in which a thermal decomposition chamber is placed, equipped with a loading device, a coke ash residue discharge hatch, and an agitator, a thermal decomposition chamber is placed in a heating chamber, the walls of which are covered with heat insulating material, there is a grate in the lower part of the heating chamber for the afterburning of the coke-ash residue, and a heating burner is placed under the thermal decomposition chamber, approx. there is a vertical cyclone furnace with an afterburner, in the upper part of which there is a burner for burning pyrolysis products, the unit is also equipped with a gas bypass to protect the thermal decomposition chamber from overheating, a gas distributor for the flue gas stream, a catalytic afterburner of organic compounds in flue gases, a heat exchanger with a fan, a cyclone , a scrubber for liquid post-treatment of flue gases from solid inclusions, a fan-smoke exhauster, which ensures that the air necessary for the process of burning a gas-vapor mixture, and the removal of flue gases into the pipe, control panel, service platform [2].

The disadvantage of the installation is its low efficiency.

The loading device of the installation is a box without a bottom with a top cover, which due to a special drive can be moved in a box located above the chamber for thermal decomposition of waste. Between the box and the box there are seals for sealing the chamber. At the time of loading the waste drawer is pulled out onto the box tray and its lid is open. After loading, the lid of the box is closed, and the box itself is moved by a special drive along the box into the area above the thermal decomposition chamber. Cold and wet waste from the box is dumped into the chamber.

This operation of the installation leads to significant heat loss, which is spent on heating parts of the loading device. The loading of a portion of cold and wet waste into the thermal decomposition chamber leads to a sharp decrease in the operating temperature and interruption of the pyrolysis process. The installation cycle increases by the time required for heating and drying the waste in the thermal decomposition chamber.

The closest technical solution adopted for the prototype is a solid waste utilization installation containing a thermoreactor, in which there is a thermal decomposition chamber, equipped with a loading device, a coke ash residue discharge hatch, and a agitator, the thermal decomposition chamber is placed in a heating chamber, the walls of which are covered with heat-insulating material, in the lower part of the heating chamber there is a grate for burning out the coke residue, and under the thermal decomposition chamber p a heating burner is located, a vertical cyclone furnace with an afterburner is adjacent to the end of the thermoreactor, in the upper part of which there is a burner for burning pyrolysis products, the unit is also equipped with a bypass duct to protect the thermal decomposition chamber from overheating, a gas distributor for the flue gas stream, a catalytic afterburner of organic compounds in the flue gases, a heat exchanger with a fan, a cyclone, a scrubber for liquid after-treatment of flue gases from solid inclusions, a smoke exhaust fan, providing An additional waste pre-heating chamber formed by fixed vertical walls and movable horizontal valves is placed between the intake air into the installation, which is necessary for the combustion of the combined-gas mixture, and the discharge of flue gases into the pipe, control panel, service platform, between the receiving hopper of the loading device and the thermal decomposition chamber moreover, the upper valve hermetically separates the preheating chamber from the receiving hopper of the loading device and the surrounding fluidized bed, and the lower valve - from the thermal decomposition chamber, the preheating chamber wall, and both valves are covered with a heat insulating material.

The disadvantage of the installation is its low efficiency.

Cold and wet waste loaded into an additional preheating chamber are caked. While the lower layers of the waste get warm and dry, the upper layers of the waste may remain insufficiently heated and humid. The loading of a portion of cold and wet waste into the thermal decomposition chamber leads to a decrease in the operating temperature and even interruption of the pyrolysis process. The installation cycle increases by the time required for heating and drying the waste in the thermal decomposition chamber.

The technical problem to which the claimed utility model is directed is to increase the efficiency of the installation.

The solution to this problem is achieved by the fact that the additional chamber for preheating the waste is equipped with agitators connected by mechanical gears with each other and with the agitator of the thermal decomposition chamber.

Comparison of the claimed device with the prototype shows that there is a presence of new parts and functional connections between them.

New details: tedders in an additional preheating chamber; mechanical gears connecting the agitators in the additional preheating chamber with each other and with the agitator of the thermal decomposition chamber.

New functional connections: agitators in an additional preheating chamber provide mixing of the entire volume of waste, which leads to uniform heating and drying of the waste in this chamber; mechanical gears connecting the agitators in the additional preheating chamber with each other and with the agitator of the thermal decomposition chamber serve to rotate all agitators from one engine.

The presence of new elements and functional relationships can increase the efficiency of the installation.

The utility model is illustrated by drawings, where in FIG. 1 shows a structural diagram of a plant for the disposal of solid waste, and in FIG. 2 is a diagram of a thermal decomposition chamber with a agitator and an unloading hatch, as well as an additional chamber for preheating waste with agitators, mechanical gears, and a receiving hopper of the loading device.

The installation (Fig. 1) contains a thermoreactor 1, a chamber for thermal decomposition of waste, a loading device 3, a hatch 4 for unloading a coke ash residue, a tedder 5, a heating chamber 6 with a grate for burning out a coke ash residue, a cyclone furnace 7, a burner 8 for heating the thermal decomposition chamber , burner 9 for burning pyrolysis products, gas distributor 10 flue gas stream, catalytic afterburner 11, heat exchanger 12 with fan 19, cyclone 13, scrubber 14 for liquid flue gas after-treatment from solid ones fan, smoke exhauster 15, chimney 16, control panel 17, service platform 18, fire door 20, lubricant-coolant tank 21, pump 22, gate 23 for vacuum control in the thermal decomposition chamber, water tank 24, valve 25 water supply, air gate 26, fuel tank 27, fuel supply valve 28, lever 29 for opening the embrasure of the burner 8.

Above the thermal decomposition chamber 2 (FIG. 2), an additional waste pre-heating chamber 30 is formed, formed by fixed vertical walls and movable horizontal valves, the upper valve 31 sealingly separating the preliminary heating chamber from the receiving hopper of the loading device 3 and the environment, and the lower valve 32 - from the thermal decomposition chamber. The walls of the preheating chamber, as well as both valves, are covered with heat-insulating material, which does not allow heating of the waste in the chamber to the temperature of their melting and the beginning of pyrolysis.

An additional chamber for preheating the waste is equipped with agitators 33 and 34, connected by mechanical gears 35 and 36 to each other and to the agitator of the thermal decomposition chamber.

Installation of solid waste disposal works as follows.

To start the installation, it is necessary from the control panel 17 (Fig. 1) to turn on the smoke exhauster 15, the heat exchanger fan 19, the lubricant-coolant supply pump 22 and close the gate 26.

Open the fuel supply valve 28, open the embrasure with the lever 29 and start the burners 8 and 9. After heating the flue gases in the heating chamber 6 to a temperature of 650 ... 700 ° C from the hopper of the charging device 3, throw a small portion of burning through chamber 30 dry waste (e.g. paper) to burn oxygen and close valves 31 and 32.

For the operation of the installation from the hopper of the loading device 3, by opening the valve 31, load a portion of waste into the additional chamber 30. With closed valves 31 and 32, withstand the waste in the additional pre-heating chamber for a certain time. By opening gate valve 32, discharge a portion of heated waste into chamber 2.

As the waste is heated, a gas-vapor mixture is released from them, which enters the furnace 7, where combustible components are burned. To prevent overheating of the chamber 2, water is supplied from the tank 24 to it using the valve 25.

In the process of disposal, the waste and coke residue in chamber 2 are periodically mixed by agitator 5. At the same time, agitators 33 and 34, connected with the agitator 5 by mechanical gears 35 and 36, mix the waste in an additional preheating chamber, preventing them from caking.

With a decrease in the temperature of the flue gases at the outlet of the thermoreactor and a simultaneous decrease in the intensity of the flame to the backlight mode, the installation cycle is considered completed. Depending on the operating mode of the installation and the composition of the waste, a new portion of the waste is loaded and the cycle repeats. Unloading of coke ash residue on the grate of the heating chamber 6 is carried out as necessary depending on the composition of the waste.

When working with high-calorie waste (for example, flammable plastics, oily waste, etc.), the time interval between downloads is reduced, and when disposing of low-calorie waste, the cycle time is increased.

Mixing the waste in an additional pre-heating chamber with agitators ensures uniform heating and drying of the entire waste volume in this chamber, which, when loading the waste into the thermal decomposition chamber, ensures a continuous pyrolysis process and increases the efficiency of the installation.

Sources of information taken into account

1. RF patent No. 2476771, cl. F23G 5/00, 2011.

2. LLC "VP - Service". Installation of utilization of solid household, industrial and medical waste ECHOUTO-150.3. TU-4859-001-53776433-2013. Operating Instructions, http://www.echutos.ru.

3. RF patent №139257, cl. F23G 5/027, 2013 (prototype).

Claims (1)

A solid waste utilization installation comprising a thermoreactor in which a thermal decomposition chamber is located, equipped with a loading device, a coke ash residue discharge hatch and a tedder, a thermal decomposition chamber is placed in a heating chamber, the walls of which are covered with heat insulating material, and there is a grate for afterburning in the lower part of the heating chamber coke residue, and a heating burner is placed under the thermal decomposition chamber, a vertical is adjacent to the end of the thermoreactor A cyclone furnace with an afterburner, in the upper part of which there is a burner for burning pyrolysis products, the unit is also equipped with a gas bypass to protect the thermal decomposition chamber from overheating, a gas distributor for the flue gas stream, a catalytic afterburner of organic compounds in flue gases, a heat exchanger with a fan, a cyclone, a scrubber for liquid post-treatment of flue gases from solid inclusions, a fan-smoke exhauster, which ensures that the air necessary for the combustion process enters the installation I gas-vapor mixture, and the removal of flue gases into the pipe, control panel, service platform, between the receiving hopper of the loading device and the thermal decomposition chamber there is an additional chamber for pre-heating waste formed by fixed vertical walls and movable horizontal valves, and the upper valve hermetically separates the pre-heating chamber from the receiving hopper of the loading device and the environment, and the lower valve - from the thermal decomposition chamber, walls The kits of the preheating chamber, as well as both valves, are coated with a heat insulating material, characterized in that the additional chamber for preheating the waste is equipped with agitators connected by mechanical gears with each other and with the agitator of the thermal decomposition chamber.

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