ES2805832T3 - Combustion plant and operating procedure of a combustion plant - Google Patents

Abstract

Procedure for the operation of a combustion installation (1) having a grate for combustion, with a combustion gas duct (3), which has nozzles (11 to 14) on opposite sides (15, 16) of the duct of combustion gases (3), through which a fluid is injected into the combustion gases, characterized in that the nozzles (11 to 14) are arranged, aligned and configured in such a way, and the pressure and flow volume of the injected fluid are adjusted in such a way that the combustion gas (38) in the combustion gas duct (3) moves back and forth in a wavy line (37).

Description

DESCRIPTION

Combustion plant and operating procedure of a combustion plant

The invention relates to a method of operating a combustion plant having a grate for combustion with a flue gas duct having nozzles on opposite sides of the flue gas duct to inject a fluid into the combustion gases. Furthermore, the invention relates to a combustion plant with a flue gas duct having nozzles on opposite sides of the flue gas duct for injecting a fluid into the flue gas.

It is known that in a combustion plant not only the primary air is varied, but also the secondary air is added to the combustion gas through different nozzles. The fluid feed into the secondary combustion zone serves to rotate the combustion gases and is intended to produce a homogeneous mixture of the combustion gases and added secondary air through the nozzles. In practice, the special nozzle designs achieve a strong swirl, which leads to a mixing of the added secondary air with the combustion gas. This is described, for example, in DE 1947 164 A, CN 102620 285 A and US 2004/0 185399 A1. The point here is to keep the combustion gas away from the walls by means of a suitable arrangement of the nozzles, and by means of suitably adapted gas flows, and to achieve an optimal mixture in the center of the duct. Combustion gases.

EP 0675323 A1 describes nozzles with which gas is fed to the rising flue gas from the sides of the flue gas duct. Document EP 2128523 A2 describes nozzles with which the rising combustion gas is swirled with secondary air and DE 102015 003 995 A1 describes a combustion plant with which the combustion gas is swirled with recirculating gas. All installations lead to an intensive mixing of the supplied gas with the combustion gas to improve overall combustion.

The object of the invention is to develop a method for operating said combustion plant.

This objective is achieved by a method with the characteristics of claim 1.

The invention is based on the knowledge that nozzles can not only be used for swirling, but can also be arranged in such a way that the flue gas moves along a wavy line in the flue gas duct. . This means that a single flue gas particle is not led in a straight line or spiral from the combustion grate into the flue gas duct. The particle is also not conducted through the flue gas duct with acceptance of the turbulence to be mixed intensively with the secondary air.

According to the invention, the flue gas particles flow through the flue gas duct in a defined wavy line. This means that essentially all the particles have a longer residence time in the conduit than would be possible with direct flow. Whereas in the case of swirling, the individual flue gas particles have a particularly long path within the flue gas duct and other particles flow through the flue gas duct particularly quickly, the exhaust guide system flue gases, as invented, means that essentially all the particles follow a longer path in the flue gas duct. This increases the residence time of the particles in the flue gas duct and all the particles have a defined residence time in a defined path. Conduction along the wavy line is possible because the hot combustion gases have a viscous consistency and can therefore be conducted in a way through the nozzles. This results in a uniform and reproducible treatment of the flue gases and prevents, especially in the peripheral areas of the flue gas duct, that the flue gas particles flow relatively straight through the flue gas duct , while other particles remain in the flue gas duct for a long time due to turbulence.

According to the invention, the nozzles are not used for swirling, as in the state of the art, but are specifically aligned in such a way that the combustion gases flow through the injected fluid in a wavy line, thus increasing the residence time within the passage of the combustion gases.

To guide the flue gases along a wavy line, the pressure, flow volume and alignment, as well as the configuration of the nozzles must be specially adjusted. Depending on the geometric configuration of the flue gas duct, the nozzle parameters can be adjusted by simple tests to achieve a defined wavy line. This wavy line must have at least three and preferably even more than four inversion points.

A liquid can also be added as a fluid, which usually evaporates as it enters the flue gas duct. It is advantageous if a gas is added as a liquid. This gas can be air or steam, for example.

Known nozzles in flue gas ducts are arranged in the flue gas duct in such a way that the nozzle has an orientation perpendicular to the wall of the flue gas duct in which it is arranged.

The solution on which the invention is based is particularly suitable for a combustion plant comprising a combustion grate and a flue gas duct with nozzles on opposite sides of the flue gas duct for injecting a fluid into the combustion gas , the nozzles being arranged, aligned and configured in such a way, as well as the pressure and the flow volume of the injected fluid adjusted such that the flue gas in the flue gas duct moves back and forth along along a wavy line and the direction of the main nozzle of the two nozzles arranged on opposite sides of the flue gas duct is at an angle of at least 5 °, preferably more than 10 °, from a line connecting the nozzle .

In particular, if there is no nozzle opposite a nozzle, it is advantageous that the direction of the main nozzle deviates from the shorter connection to the opposite side of the flue gas duct by at least 5 °, preferably more than 10 °.

With respect to a horizontal line, it is advantageous that the direction of the main nozzle of at least one nozzle deviates from a horizontal plane in the flue gas duct by at least 5 °, preferably more than 10 °.

It is advantageous if the flue gas flow from the combustion grate widens in the direction of the flue gas flow.

Such a widening of the flue gas duct leads to an inverted nozzle and thus to a decrease in the flow velocity in the flue gas duct. Thus, additionally or alternatively to the movement of the flue gases in a wavy line, it is proposed to reduce the flow rate of the flue gases in the flue gas duct by widening the flue gas duct. By expansion of the flue gas duct is meant a cross section of the flue gas duct that widens in the direction of the flow of the flue gases. The direction of the flow of the combustion gases in the case of a wavy line is understood as the connection of the reversal points of the wave.

An embodiment of the combustion plant that is also relevant to the invention establishes that the flue gas duct has a lower and an upper zone and that the access of the combustion grate to the flue gas duct is arranged in the lower zone shifted to upper zone.

While the flue gases flow essentially upward in the flue gas duct and the residence time in the flue gas duct can be increased by moving the flue gases along a wavy line and / or by widening the flue duct. flue gas, the residence time in the flue gas duct can also be increased by moving the grate access to the flue gas duct to the rest of the flue gas duct without changing the height of the grate.

A special embodiment provides that at least one nozzle is arranged on the combustion grate in the direction of the flow of the combustion gas, in front of the flue gas duct, on a wall opposite the combustion grate to inject a fluid in the combustion gas.

The object of the invention is also achieved by a method in which the combustion air is added as primary combustion air and secondary combustion air or as secondary combustion air during the operation of the combustion plant, variably distributed in various feeding points. Although normally the incorporation of the combustion air is optimized and is not modified during the operation of the combustion plant, the invention proposes to vary the distribution of the combustion air to different feed points during the operation of the combustion plant.

It is known that in combustion plants in the region of the combustion grate the primary air varies, according to an optical analysis of the combustion in the combustion grate, transversely to the direction of transport in the combustion grate. What is new, however, is the variation in the air supply between the primary and secondary combustion air and the variation within the different secondary air supply points. It is particularly advantageous if the proportion of combustion air (A) is kept constant during the variation.

Combustion air can be supplied distributed to the nozzles and the combustion grate or the distribution of the partial volume flows to these nozzles can be varied in a controlled manner.

It is particularly advantageous if the distribution of the combustion air to the individual NOx, CO and / or O2 feed points is optimized during the operation of the combustion plant. This means that to optimize parameters such as NOx, CO and / or O2, the volume flow distribution of the feed in the Individual nozzles and / or on the nozzles and the combustion grate is modified during the operation of the combustion system.

Additionally or alternatively, it is provided that the distribution of the combustion air is distributed to the nozzles of the flue gas duct in such a way that almost constant total combustion per unit time is achieved. In this way, the total combustion of gases and / or solids can be optimized.

The nozzles make it possible to vary the height of the total combustion plane within the flue gas duct and analyze the total combustion as a function of the height in the flue gas duct by means of measurements and, depending on this, vary the fluid feed through the nozzles in such a way that, for example, a certain degree of total combustion is not below a certain height of the flue gas duct.

An advantageous embodiment example is shown in the drawing and explained in more detail below. Figure 1 is shown schematically the arrangement of the fluid supply points in a combustion plant and Figure 2 schematically a wavy line of flue gases in a flue gas duct. The combustion plant 1 shown in figure 1 has a combustion grate 2 and a flue gas duct 3. Arrows 4 indicate the supply of primary air in the combustion grate 2 and arrows 5 to 9 indicate the secondary air supply through nozzles. Nozzles 10-14 are only shown schematically. The nozzle 10 is located on the combustion grate 2, the nozzles 11 and 12 are located on one side 15 of the flue gas duct 3 and the nozzles 13 and 14 are located on the opposite side 16 of the flue gas duct 3 .

Dotted lines 17 through 21 indicate the main direction of nozzles 10 through 14.

In the direction of the main nozzle 17, angle 22 shows the orientation relative to a line 23 connecting nozzles 12 and 14. Angle 24 shows the orientation of the direction of the main nozzle 17 relative to the shorter connection 25 of the nozzle 14 to the opposite side 15 of the flue gas duct 3. Angle 26 finally shows the direction of the main nozzle 17 of the nozzle 14 in relation to a horizontal plane 27 in the flue gas duct 3.

The two opposite sides 15 and 16 of the flue gas duct 3 form an angle 28 between them, so that the flue gas duct 3 widens conically in the area between the access 29 to the flue gas duct 3 and a transition 30 to the vertical sides 31 and 32 of the flue gas duct 3. In this way a lower section 33 of the flue gas duct 3 is created between the access 29 of the combustion grate 2 to the flue gas duct 3 and the transition 30 from section 33 of the flue gas duct 3 with sloping sides 15, 16 to section 34 of the flue gas duct with vertical walls 31 and 32, which is arranged offset towards this second section 34 between the vertical walls 31 and 32. The nozzle 10 with its main nozzle direction 21 is arranged on a wall 35 located in front of the combustion grate 2 and therefore is in an area 36 above the combustion grate ion 2 and before entry into the lower area 33.

During the operation of the combustion plant 1, through the nozzles 10 to 14 a wavy line 37 of the combustion gases 38 is formed which is produced in the combustion grid 2. Adding secondary combustion air 39 to 43 as gas to the combustion gases 38, the wavy line 37 is formed with its reversal points 44 to 48. The primary combustion air 49 is fed to the combustion plant 1 through the grid 2.

This makes it possible to feed combustion air in such a way that the combustion gas 38 flows in the wavy line 37. A preferred method also provides that the secondary combustion air 39 to 43 or the primary combustion air 49 and the secondary combustion air 39 to 43 are added during the operation of the combustion plant as volumetric flow or mass flow, in a variable quantity, distributed to the different feeding points on grid 2 or on nozzles 10 to 14. The proportion of combustion air can vary during the operation of the combustion system. However, it is advantageous if the proportion of combustion air is kept constant.

The sensors 50, 51 and 52 for NOx, CO and / or O2 are connected to a controller 53 to optimize the distribution of the combustion air, formed by the primary combustion air 49 and the secondary combustion air 39 to 43, to the points individual feeding.

Total combustion can be determined from the measured values determined with sensors 50 to 52 and this allows the distribution of the combustion air to the nozzles to be adjusted in such a way that the total combustion per unit time remains almost constant.

Claims (17)

1. Procedure for the operation of a combustion installation (1) that has a grate for combustion, with a flue gas duct (3), which has nozzles (11 to 14) on opposite sides (15, 16) of the combustion gas duct (3), through which a fluid is injected into the combustion gases, characterized in that the nozzles (11 to 14) are arranged, aligned and configured in such a way, and the pressure and volume Flow rates of the injected fluid are adjusted such that the flue gas (38) in the flue gas duct (3) moves back and forth in a wavy line (37). 2. Method according to claim 1, characterized in that the fluid is a gas. 3. Method according to claim 2, characterized in that the gas is air. 4. Process according to claim 2, characterized in that the gas is steam. 5. Process according to one of the preceding claims, wherein the wavy line (37) has at the least three and preferably more than four reversal points (44 to 48). 6. Process according to one of the preceding claims, characterized in that at least a portion of the combustion air (39 to 43 and 49) is fed to the flue gas (38) through the nozzles (11 to 14) and the air Combustion (39 to 43 and 49) is added as primary combustion air (49) and secondary combustion air (39 to 43) or as secondary air (39 to 43) during the operation of the combustion plant (1), distributed variably at various feeding points (2, 10 to 14). 7. Method according to claim 6, characterized in that the proportion of combustion air is kept constant. 8. Process according to claims 6 or 7, characterized in that the combustion air (39 to 43 and 49) feeds distributed on the nozzles (10 to 14) and the combustion grate (2). 9. Process according to one of claims 6 to 8, wherein the flow distribution partial volume to the nozzles (10 to 14) is varied in a controlled manner. 10. Process according to one of claims 6 to 9, characterized in that during operation of the combustion plant (1) the distribution of the combustion air (39 to 43 and 49) to the feed points (10 to 14, 4) individual is carried out in an optimized way for NOx, CO and / or O ² . 11. Process according to one of claims 6 to 10, characterized in that the distribution of the combustion air (39 to 43 and 49) is distributed to the nozzles (10 to 14) so that total almost constant combustion is achieved (combustion total gas and / or solids) per unit of time. 12. Combustion plant with a combustion grate and a flue gas duct (3) having nozzles (11 to 14) on opposite sides (15, 16) of the flue gas duct (3) to inject a fluid in the combustion gases, characterized in that the nozzles (11 to 14) are arranged, aligned and configured in such a way, as well as the pressure and the flow volume of the injected fluid can be adjusted in such a way that the combustion gas ( 38) in the flue gas duct (3) moves back and forth in a wavy line (37) and the main nozzle direction (17 to 20) of the two nozzles (11 to 14) arranged on opposite sides (15, 16) of the flue gas duct (3) forms an angle (22) of at least 5 °, preferably more than 10 °, with respect to a line (23) connecting the nozzles (11 to 14) . 13. combustion plant according to claim 12, characterized in that the main direction of nozzle (17 to 21) of a nozzle (11 to 14) deviates from the shortest connection (25) to the opposite side (15, 16) flue gas outlet (3) at an angle (24) of at least 5 °, preferably more than 10 °. 14. combustion plant according to claims 12 or 13, characterized in that the main direction of nozzle (17 to 21) at the least one nozzle (10 to 14) deviates from a horizontal plane (27) in the conduit gas combustion (3) at an angle (26) of at least 5 °, preferably more than 10 °. 15. combustion plant according to one of claims 12 to 14, wherein the combustion gas duct (3) widens from the combustion grate (2) in the direction of the flow of the flue gas (38). 16. combustion plant according to one of claims 12 to 15, wherein the flue gas duct (3) has a lower region (33) and an upper region (34) and the lower region (33) access ( 29) from the combustion grid (2) to the flue gas duct (3) is arranged offset towards the upper region (34). 17. combustion plant according to one of claims 12 to 16, characterized in that at the least one nozzle (10) is arranged above the combustion grate (2) in the direction of flow of the flue gases (38) before the outlet of the combustion gases (3) in a wall (35) opposite the combustion grate (2) to inject a fluid into the combustion gases (38).