RU52977U1 - BOILER OF THE BOILING LAYER - Google Patents

Abstract

The utility model relates to a power system and can be used as industrial, heating and energy boilers of a fluidized bed, burning ground solid fuel and combustible waste. The fluidized bed boiler contains a firebox with a downstream air distribution grill for supplying primary air under the fluidized bed and burning crushed solid fuel in a fluidized bed, front, rear and side walls with fire screens forming the firebox volume, fuel input devices above the fluidized bed, nozzles for secondary blast feed. Ash collectors with precipitation bins and ablation return ejectors are installed in the boiler flues. The lower parts of the front and rear enclosing walls are made inclined with the formation of expansion upward of the volume of the furnace. The front wall is made with a ledge inside the firebox, which is the ceiling area. The nozzles for the supply of secondary blast are located on the ceiling section of the front wall and on the rear wall with respect to each other mainly at the same height. At the same time, nozzles for supplying secondary blast located on the ceiling section of the front wall are directed downwards towards the air distribution grill, and nozzles for supplying secondary air located on the rear wall are directed towards the nozzles located on the ceiling section. The utility model allows to increase the efficiency of fuel combustion and reduce the amount of solid emissions from a fluidized bed boiler.

Description

The utility model relates to a power system and can be used as industrial, heating and energy boilers of a fluidized bed, burning ground solid fuel and combustible waste.

Known fluidized bed boiler containing a furnace with a downstream air distribution grill for supplying primary air under the fluidized bed and burning crushed solid fuel in a fluidized bed, front, rear and side enclosing walls forming the volume of the furnace, a nozzle for supplying ground fuel with secondary air in the form aerosol mixtures, a nozzle for supplying secondary blast at a speed of 25-35 m / s and with a momentum equal to 8-22 of the amount of air movement in the aerosol. The furnace is made of upper and lower chambers connected by a window. A nozzle for supplying ground fuel with secondary air connected to the upper chamber and a nozzle for supplying secondary blast associated with the lower chamber are mounted on opposite sides in the superlayer volume of the furnace tangentially to the conventional horizontal body of rotation. In this case, the nozzle for supplying the secondary blast is located below the nozzle for supplying the ground fuel with secondary air, and the air jets from the nozzle for supplying the secondary blast are oriented under the area of formation of the jets of air mixtures from the nozzle for supplying the ground fuel with secondary air. The vortex flow, which is a conditional horizontal body of revolution, and created by jets of air mixture and air from these nozzles, provides mixing of the flue gases and efficient use of secondary blast in the superlayer volume of the furnace (copyright certificate SU 1453118, MKI ⁴ F 23 C 6/04).

The described fluidized bed boiler has the following disadvantages:

- low efficiency of fuel combustion due to the need for nozzles to supply a large amount of secondary air, since for the organization of the vortex flow of flue gases heavily loaded with products of incomplete combustion of fuel carried out from the fluidized bed, a much larger pulse of secondary blasting is required than with layered or pulverized coal combustion, from - due to significant losses with flue gases;

- an increased amount of solid emissions, that is, fly ash, into the upper part of the furnace and the convective part of the boiler and associated with this large heat loss with mechanical unburning, as well as dust from the boiler. The increased amount of solid emissions is due to the supply of a large mass of unburned fuel particles with a high speed under the region of formation of the aerosol mixture jets from the nozzle for supplying ground fuel with secondary air, where unburned particles penetrate secondary air jets due to inertia and penetrate into the upper part of the furnace, into the low , about 800-900 ° С, temperatures and then to the convection part of the boiler, where they do not have time to burn out completely, which also leads to increased mechanical underburning and an additional decrease in eff combustion injective.

Closest to the proposed utility model (prototype) is a fluidized bed boiler containing a firebox with an air distribution grill located below for supplying primary air under the fluidized bed from a fan and burning crushed solid fuel in a fluidized bed, front, rear and side enclosing walls with furnace screens, forming the volume of the furnace, a device for introducing fuel above the fluidized bed, nozzles for supplying a secondary blast located on opposite front and rear enclosing walls. Ash collecting devices with precipitation bins and ablation return ejectors are installed in the flues. The lower part of the rear enclosing wall is made inclined with the formation of expansion upward of the volume of the furnace. The front wall is made with a ledge inside the firebox, which is the ceiling

plot. The nozzles for supplying the secondary blast are located tangentially to the conditional body of revolution on the ceiling section of the front wall and the rear wall. In this case, the nozzles located on the ceiling section are directed toward the inclined section of the rear enclosing wall, and the nozzles mounted on the rear enclosing wall below the nozzles located on the ceiling section are oriented downward towards the air distribution grill. The ablation return ejectors with a precipitation hopper are connected to the fan and connected to the secondary blast nozzles located on the rear enclosing wall. Thus, part of the secondary air is introduced into these nozzles separately and / or together with the fuel and products of incomplete combustion trapped behind the furnace. The near-wall zone of the ceiling section in the superlayer volume of the furnace is a section of the flow. The use of secondary blast nozzles leads to an active vortex movement of the flue gases in the superlayer space of the furnace, which facilitates mixing of fuels and oxidizing agent (patent RU 2217658, IPC ⁷ F 23 C 10/18, 5/24).

The main disadvantages of the fluidized bed boiler, selected as a prototype, are reduced fuel combustion efficiency, increased amount of solid emissions, that is, fly ash, from the boiler, and the associated large heat loss with a mechanical burnout. These shortcomings are due to the fact that in the near-wall zone of the ceiling section, which is a section of the flow, there is a maximum velocity profile (Schlichting G. Theory of the boundary layer / G. Schlichting. - M .: Nauka, 1974). The flow of flue gases circulating in the superlayer volume picks up unburned fuel particles and particles of fuel introduced into the furnace above the fluidized bed carried out from the fluidized bed and directs them to the run-in section, where they are separated by the inertia forces to the walls. At the same time, due to the high speed, their significant fraction of inertia breaks through the jets of secondary air, or freely penetrates between them, and enters the upper part of the furnace, in the low zone, of the order of 800-900 ° С,

temperatures, and, then, into the convection part of the boiler, where these particles do not have time to burn out completely.

The objective of this utility model is to increase the efficiency of fuel combustion and reduce the amount of solid emissions from a fluidized bed boiler.

To achieve the technical result in a fluidized bed boiler containing a firebox with an air distribution grill located below for supplying primary air under a fluidized bed and burning crushed solid fuel in a fluidized bed, front, rear and side walls with fire screens forming the volume of the firebox, input devices fuel above the fluidized bed, nozzles for supplying secondary blast, ash collecting devices installed in the gas ducts of the boiler with sedimentation hoppers and ablation return ejectors, Moreover, the lower part of the rear enclosing wall is inclined to form an upward expansion of the volume of the furnace, the front enclosing wall is made with a step deep into the furnace, which is the ceiling section, and nozzles for supplying secondary blast are located on the ceiling section of the front enclosing wall and the rear enclosing wall, according to a useful nozzle model for the supply of secondary blast, installed on the ceiling section of the front and rear enclosing walls, are located in relation to each other mainly on the same height. The secondary blast nozzles located on the ceiling section of the front wall are directed downward towards the air distribution grill, and the secondary air nozzles located on the rear wall are directed towards the nozzles located on the ceiling section.

Improving the efficiency of fuel combustion and reducing the amount of solid emissions from the fluidized bed boiler is ensured by the fact that the nozzles for supplying secondary blast located on the ceiling section of the front wall of the fence are predominantly at the same height

to the side of the air distribution grill, and nozzles for supplying secondary blast placed on the rear wall, to the side of the nozzles located on the ceiling section, leads to the complete absence in the wall zone of the ceiling section of the leakage of unburned fuel particles and fuel particles introduced into the furnace above the fluidized bed , to the upper part of the furnace, to the zone of low temperatures, and to the minimum penetration of these particles in the zone of operation of nozzles for supplying secondary blast placed on the rear wall of the enclosure, since in this zone longitudinal flow of flushing the inner surface of the rear boundary wall, characterized by the absence of peaks of the velocity profile and a uniform concentration of solids, i.e. fly ash stream.

The utility model is illustrated in the drawing, which schematically shows a fluidized bed boiler, a longitudinal section.

The drawing further shows the following:

- primary air supply directions indicated by solid lines with arrows;

- fuel supply directions indicated by dashed lines with arrows;

- secondary air supply directions indicated by dot-and-dash lines with arrows;

- the direction of the exit of flue gases from the boiler, indicated by parallel horizontal lines with arrows;

- expansion of the volume of the furnace, marked by a closed dashed line;

- the direction of the vortex motion of gaseous and solid products of incomplete combustion of fuel, marked by a closed oval line with two arrows.

The fluidized bed boiler contains a furnace 1 with a downstream air distribution grill 2 for supplying primary air along the path 3 from the fan 4 under the fluidized bed 5 and burning the crushed solid

fuel in a fluidized bed 5. The volume 6 of the furnace 1 is formed by the enclosing walls - front 7, rear 8 and two side (not indicated in the drawing), protected by fire screens - front 9, rear 10 and two side (not indicated) from high temperatures and for cooling flue gases. The front 7 and rear 8 enclosing walls, equipped with furnace screens 9 and 10, respectively, in the lower part of the furnace 1 are made inclined at an angle of 50-55 ° to the vertical with the formation of an expansion upward of the volume 6 of the furnace 1, which is marked in the drawing by a closed curve with a dashed line. The front 7 enclosing wall above the expansion of the volume 6 of the furnace 1 is made with a step deep into the furnace 1, which is a horizontal (not shown in the drawing) or inclined ceiling section 11.

On the ceiling section 11 of the front 7 of the enclosing wall, nozzles 12 for supplying a secondary blast are installed, and on the vertical part of the rear 8 of the enclosing wall above the upward expansion of the volume 6, the furnaces 1 are located mainly at the same height as the nozzles 12 of the nozzle 13 for supplying a secondary blast. The nozzles 12 are directed downward towards the air distribution grill 2 vertically (not shown in the drawing) or at an angle of 14 to the vertical, which is no more than 15 °. The nozzles 13 are directed towards the nozzles 12 horizontally (not shown in the drawing) or at an angle of 15, which is no more than 45 ° to the horizontal. In the walls 7, 8 above the fluidized bed 5, fuel injection devices 16 are placed. Ash collectors 17 with settling hoppers 18, ablation return ejectors 19, which are connected by ducts 20 to the fan 4, are installed in the boiler flues. There are other elements necessary for servicing and operating the fluidized bed boiler.

The proposed device operates as follows.

In the fluidized bed 5 on the air distribution grill 2, particles of ash and burning coal formed by crushed solid fuel, which is supplied from the fuel input devices 16, heated to 800-1000 ° C,

they are maintained in a fluidized state and intensively mixed by blowing through a layer of primary air from the fan 4 along the path 3. Gaseous and solid products of incomplete combustion of fuel carried out from the fluidized bed 3, and the fuel fines picked up by the stream are burned in the superlayer space in a vortex formed in the expansion volume 6 of the furnace 1 by supplying secondary air nozzles 12 and 13 of the secondary blast.

The vortex flow in the expansion of the volume 6 of the furnace 1 contributes to good mixing of gaseous and solid products of incomplete combustion of fuel and oxidizer and provides a more uniform thermal perception of the front 9, rear 10 and side furnace screens and, therefore, their reliable operation.

From the furnace 1, the combustion products are removed by a smoke exhaust (not shown in the drawing).

Compared with the fluidized bed boiler, selected as a prototype, in the wall zone of the ceiling section 11 with nozzles 12 installed there is completely no breakthrough of unburned fuel particles and fuel particles introduced into the furnace 1 above the fluidized bed 5, into the upper part of the furnace 1, in low temperature region. The breakthrough of these particles in the zone of the vertical section of the upper part of the rear 8 of the enclosing wall with the nozzles 13 installed on it is minimal, since in this zone there is a longitudinal washing of the wall surface in the absence of maximums of the velocity profile and with a uniform concentration of the solid phase in the stream.

Ash collectors 17 built into the gas ducts of the boiler with precipitation bins 18 and ejection return ejectors 19 fulfill a dual function, providing, on the one hand, more complete burning of fuels in the ablation, and, on the other, a high concentration of particles in the furnace 1 and, accordingly, intensive cooling of the combustion products by the combustion screens. In this case, the implementation of the lower parts of the front 7, rear 8 enclosing walls with furnace screens 9, 10 inclined increases the heat removal of these

sections in comparison with the vertical parts of these walls with screens in 1.5-2.5 times.

Thus, the use of the proposed device in comparison with the prototype allows to increase the efficiency of fuel combustion, reduce the amount of solid emissions from the boiler fluidized bed and heat loss with a mechanical burnout.

Claims (1)

A fluidized bed boiler containing a furnace with a downstream air distribution grill for supplying primary air under the fluidized bed and burning crushed solid fuel in a fluidized bed, front, rear and side walls with fire screens forming the furnace volume, fuel input devices above the fluidized bed, nozzles for supplying secondary blasting, ash collecting devices installed in the gas ducts of the boiler with precipitation bins and ejection return ejectors, the lower part of the rear enclosing wall being made and inclined with the formation of expansion upward of the volume of the furnace, the front enclosing wall is made with a step deep into the furnace, which is the ceiling section, and nozzles for supplying a secondary blast are located on the ceiling section of the front protecting wall and the rear enclosing wall, characterized in that the nozzles for supplying the secondary blast, installed on the ceiling section of the front and rear enclosing walls, are located relative to each other mainly at the same height, with nozzles for supplying secondary blast located wedges on the ceiling section of the front wall, are directed downward towards the air distribution grill, and nozzles for supplying secondary air located on the rear wall of the fence are directed towards the nozzles located on the ceiling section.