RU45177U1 - Waste Incinerator - Google Patents

Abstract

The utility model can be used for disposal of solid and liquid domestic and industrial waste. Objective: ensuring the completeness of burning of garbage, regardless of its quality composition while reducing emissions of harmful components into the atmosphere. SUBSTANCE: waste incinerator installation comprising a furnace, a garbage supply unit, a heat recovery unit for gaseous products of combustion, a slag unloading device, an ash removal unit, an air supply means, a chimney and a chimney, characterized in that the furnace is made in the form of a drum lined with heat-resistant material, for example , with a chamotte, mounted horizontally with the possibility of rotation around the longitudinal axis, while the debris feeder includes a hopper provided with a shutter connected to the receiving hole of the furnace by means of a hermetic case, the cavity of which is connected with the air supply channel, while the end face of the furnace is open to the afterburner, the lower part of which is made in the form of a slag receiving hopper and is equipped with an additional air supply channel, and the heat recovery unit of the gaseous products of combustion is made in the form of a heat exchange chamber, in the cavity of which a heat exchange section is placed, gas ducts of which are arranged vertically, while the upper end of the heat exchange chamber is connected by a gas channel to the upper end of the afterburner, and its lower the end is connected to the chimney with a chimney and is equipped with ash removal equipment. In addition, the afterburner is made of heat-resistant material, such as fireclay.

Description

The utility model relates to devices for waste disposal by incineration can be used for the disposal of solid household and industrial waste.

Known waste incinerator containing a sorting device, a furnace for the pyrolysis of carbon-containing materials, the output of which through a disintegrator communicates with an underground gas generator (see, Pat. RF №2156406, 2000).

The disadvantage of this solution is the bulkiness of the production line, air pollution, insufficient controllability of the gas generator, as a means of burning pyrolyzed carbon-containing material, in addition, such a installation can be implemented geographically only if there are coal reserves or bitumen shale.

Also known is a waste incinerator containing a furnace, a garbage supply unit, a heat recovery unit for gaseous products of combustion, a slag unloading unit, an ash removal unit, an air supply means, a chimney and a chimney, (see w / Around the World No. 12, 2001 pp. 120-125 or caUThttp: // www / ecolog / info / stati / img / 44_shemal / png).

The disadvantage of this installation is the need for preliminary preparation of garbage (for example, removal of low-melting components (plastics, tar, etc.), since on the grate grates these substances turn into liquid and flow into the armrest space before they burn out. In addition, garbage in these furnaces pressed, at the same time, its upper layers, burning, become covered with a crust of foamed slag, which isolates them from thermal effects, so the lower layers of garbage, when unburned, are thrown into an ash pan and require repeated hydrochloric utilization. In addition, to maintain the operating temperature within the chamber

Combustion has to use additional fuel (up to 15% by weight per unit of waste burned). In addition, the installation has large dimensions. All this reduces the efficiency of the process of burning garbage, reduces its environmental friendliness, increases its resource intensity.

The problem to which the stated solution is directed is expressed in ensuring the completeness of burning of garbage, regardless of its quality composition while reducing emissions of harmful components into the atmosphere.

The technical result achieved in solving the problem is expressed in eliminating the need for preliminary garbage preparation (for example, removing fusible components (plastic, tar, etc.), eliminating the consumption of additional fuel, completely burning the garbage, and reducing emissions of harmful components into the atmosphere before MPC. , the installation has a simple design and relatively small dimensions, which allows it to be used as a heat generator.

To solve this problem, an incineration plant containing a furnace, a waste feed unit, a heat recovery unit for gaseous products of combustion, a slag unloading device, an ash removal unit, an air supply means, a chimney and a chimney is characterized in that the furnace is made in the form of a drum lined with heat-resistant material , for example, chamotte, mounted horizontally with the possibility of rotation around the longitudinal axis, while the garbage feed unit contains a hopper provided with a shutter connected to the firebox receiving hole and by means of a sealed housing, the cavity of which is connected with the air supply channel, while the end face of the furnace is open to the afterburner, the lower part of which is made in the form of a slag receiving hopper and is equipped with an additional air supply channel, and the heat recovery unit for the gaseous products of combustion is made in the form of a heat exchange chamber, the cavity of which is placed heat exchange

section, the gas ducts of which are arranged vertically, while the upper end of the heat exchange chamber by a gas channel is connected to the upper end of the afterburner, and its lower end is connected by a chimney to the chimney and is equipped with ash removal equipment. In addition, the afterburner is made of heat-resistant material, such as fireclay.

A comparison of the features of the claimed solutions with the features of the prototype and analogues indicates its compliance with the criterion of "novelty."

The combination of features characterizing the utility model ensures the completeness of burning of garbage, regardless of its quality composition while reducing emissions of harmful components into the atmosphere.

Figure 1 shows a longitudinal section of the installation; figure 2 is a horizontal section through a heat exchange chamber.

The drawings show a firebox made in the form of a drum 1 mounted horizontally with the possibility of rotation around the longitudinal axis 2 and lined with heat-resistant material 3, for example, chamotte. The drum supports that ensure its rotation are also shown, one of which is made in the form of a trunnion 4, and the second is made as a fixed socket 5 through the opening of which the drum housing 1 is passed. The named supporting elements are rigidly fixed in space on a common foundation. The mechanism of rotation of the drum is made according to the known scheme and includes a toothed belt 6 fixed on the outer surface of the drum 1, with which a drive wheel 7 is attached, mounted on a shaft 8 of a low-speed electric motor 9 (or an electric motor reducer).

In the axle 4 there is a receiving opening of the furnace, for which, the outlet end of the sealed housing 10 is passed through the axle, the receiving opening of which is the outlet of the hopper 11 provided with a shutter 12, while the sections of the walls of the sealed housing 10 in contact with the garbage are provided with a water jacket 13, In addition in addition, the sealed housing 10 by means of the air supply channel 14,

equipped with an air damper 15, is connected to an air source, for example, a fan (not shown in the drawings).

One end of the drum 1 is inserted into the pin 4 (in fact, forming its end wall), and the second, with the possibility of rotation and using known means of sealing the butt joint, is passed through the wall of the afterburner 16, the lower part of which is located below the end of the furnace, made in the form of a slag receiving hopper 18 (with a locking flap - not shown in the drawings) and provided with an additional air supply channel 19 with an air flap (not shown in the drawings).

The upper end 20 of the heat exchange chamber 21, by a gas channel 22, is connected to the upper end 23 of the afterburner 16, and its lower end 24 is connected by the chimney 25 to the chimney 26. The lower end of the heat exchange chamber 21 is equipped with ash removal means, for this the lower part of the chamber can be made in the form of an ash receiving hopper 27 with a corresponding shutter 28, or equipped with mechanical pushers, scraper conveyors, etc. mechanisms. In addition, the gas ducts 29, the heat exchange section, are arranged vertically.

The walls of the drum 1 (the furnace and the surface of the trunnion 4 facing it) and the afterburner 16 are made of heat-resistant material, for example, fireclay bricks (the afterburner is made in the form of a rectangular vertical well, the longitudinal axis of which is directed vertically upward, while its inner cavity is lined with fireclay brick in a checkerboard pattern, for better mixing coming from the furnace, gases (gasification products and sublimation of garbage and fuel) with atmospheric oxygen (coming from an additional air supply channel 19). The shell of the drum 1, the heat exchange sections of the heat exchange chamber 21 and the control flaps are made of metal. The walls of the heat exchange chamber (except for separating it from the afterburner)

made of ordinary brick or metal. The heat exchange section is made in a known manner, for example, in the form of a sealed cavity of metal through which a bundle of vertically placed gas ducts 29 made of metal pipes is passed. The heat exchange section, by means of appropriate nozzles, is connected to a heated water accumulator or heat supply system (the elements mentioned here are not shown in the drawings). Depending on the type of fuel (solid or liquid), the type of fuel supply unit changes (solid disintegrated fuel is mixed with garbage and fed into the furnace, liquid is burned using appropriate burners forming a combustion torch in the furnace volume).

The claimed installation works as follows. The furnace is put into operation, burning fuel without debris in it, until it warms up (at the inlet - about 600-800 ° С, at the outlet - about 1100-1200 ° С). When burning fuel, the walls of the furnace and other elements of the furnace made of fireclay are heated. The combustion of fuel is supported by atmospheric oxygen entering the furnace through the air supply channel 14 and then the sealed housing 10.

Then they start the supply of garbage. Garbage is fed into the furnace continuously, in discrete portions, from the hopper 11 through an airtight housing 10, cutting them off with a shutter 12. At the same time, the water circulating in the water jacket 13 does not allow thermal radiation from the furnace to ignite or melt the incoming garbage. Then the garbage enters the firebox (drum 1) rotating in the axle 4 and the fixed socket 5. The fireclay lining of the drum 1 has a large thermal inertia, which allows maintaining a high temperature in the firebox even when garbage with a high moisture content arrives, which eliminates the need for use additional fuel. The absence of grate in the furnace allows you to burn liquid, and solid fusible waste. The rate of incineration increases due to

constant mixing and grinding the contents of the drum 1, during its rotation. The latter at the same time provides directed general advancement of non-combustible residues to the slag receiving hopper 18. Air is supplied both to the furnace and to the afterburner 16 through the corresponding flaps, which regulate its supply.

Gases heated in the furnace (CO, methane, dusty unburned fuel particles, etc.) - gasification products and sublimation of garbage and fuel are heated and since there is no heat removal in the furnace, they “float” into its upper part and enter the furnace through the open end the lower end of the afterburning chamber, where they interact with oxygen in the air coming through an additional air supply channel 19.

The walls of the chamber heated by hot gases give part of their heat to additional air, as well as the slag mass coming from the furnace, which ensures its heating, before this air comes into contact with gases and other products of gasification and sublimation of solid fuel). The reaction of air with gases and other products of gasification and sublimation of fuel and garbage, produces heat, therefore, the combustion products of the flue gases do not cool down and tend to the upper end of the afterburner. With the passage of gases through the afterburning chamber 16, their temperature rises above 1500 ° C. In this case, all possible combustible particles and gases are burned without forming soot on the walls of the chamber, which contributes to better heat transfer. The pressure of the pop-up gases, the hot gaseous products of combustion, are displaced from the afterburning chamber into the heat exchange chamber through the gas channel 22.

Upon receipt of garbage containing rubber and plastics, a large amount of soot is formed, which burns up without residue in the afterburner 16 when the forced air supply through the corresponding air damper. When air enters through this damper, ash is cooled and air passes into the chamber

afterburning 16 heated.

The installation does not use forced pressurization of air or smoke exhausters, as the heat exchange chamber itself is an intermediate air pump, operating due to the temperature difference entering and exiting flue gases from it.

Also, special cleaning cyclones are not used, because This function is performed by the heat exchange chamber. In it, the volume of flue gases expands and the speed of gas flows decreases and since there is no turbulence of the air, cooled ash (fly ash) falls to the bottom in the lower part of the heat exchange chamber (ash hopper 27 - from where it is dumped when the shutter 28 is opened).

In the heat exchange chamber 21, the hot gaseous products of combustion are in contact with the heating surfaces of the heat exchange sections. As a result of this, they quickly cool down and flow down their gas ducts 29, giving up their heat to the water filling the annular space. Hot water is used depending on the adopted scheme - it is either discharged into the heated water accumulator (not shown in the drawings) or into the heating system.

The cooled gases, the temperature of which does not exceed 100 ° C, enter through the chimney 25 into the chimney 26. At the exit of the chimney 26, the gases are colorless and do not contain particles of soot and smoke.

The ability to control the volume of additional air (through the damper regulating a given overlap of the channel 19 for supplying additional air) provides the possibility of optimizing the combustion process depending on the amount of fuel burned.

Claims (2)

1. An incinerator containing a furnace, a waste supply unit, a heat recovery unit for gaseous products of combustion, a slag unloading unit, an ash removal unit, an air supply means, a chimney and a chimney, characterized in that the furnace is made in the form of a drum lined with heat-resistant material, for example , chamotte mounted horizontally with the possibility of rotation around the longitudinal axis, while the garbage feed unit contains a hopper provided with a shutter connected to the receiving hole of the furnace by means of a tight housing, the cavity of which is connected with the air supply channel, while the end of the furnace is open to the afterburner, the lower part of which is made in the form of a slag receiving hopper and is equipped with an additional air supply channel, and the heat recovery unit for the gaseous products of combustion is made in the form of a heat exchange chamber, in the cavity of which a heat exchange section, the gas ducts of which are arranged vertically, with the upper end of the heat exchange chamber being connected by a gas channel to the upper end of the afterburner, and its lower end Knit chimney with a chimney and with means deashing. 2. The incinerator according to claim 1, characterized in that the afterburner is made of heat-resistant material, for example, chamotte.