DE4027040C1 - Non-catalytic removal of nitric oxide from waste gases - by injecting reducing agent into gases via nozzles - Google Patents

Abstract

In a process of non-catalytic removal of NO from waste gases, partic. from refuse incineration plants, a redn. agent is injected into the gases at 700-1100 deg.C via nozzles, which are cyclically subjected to redn. agent flow at constant redn. agent supply. For each cycle stage, the NO concn. in the gas stream is measured and the nozzle and/or redn. agent part stream distribution is determined which led to the lowest NO concn., this arrangement being followed subsequently. ADVANTAGE - No removal can be carried out as a function of measured concn., taking into account local variations.

Description

The invention does not relate to a selective method catalytic denitrification of exhaust gases, in particular Flue gases from waste incineration plants, in which the Exhaust gas stream is a reducing agent at an exhaust gas temperature from 700 to 1100 ° C, preferably 850 to 1050 ° C, about a lot of injection points is supplied to one maintain the specified NO concentration in the exhaust gas.

Such a method is known from DE-PS 24 11 672. By adding the reducing agent, such as. B. gaseous ammonia, aqueous solutions of ammonia, urea or the like., The NO _x , especially NO, are converted into the harmless substances N ₂ and H ₂ O. Compliance with the reaction temperature range is crucial for the effectiveness of the process. Below the temperature range, the reduction is inadequate and the reducing agent is discharged partly unused as an increased ammonia slip with the exhaust gas stream. Above the temperature range, the process becomes increasingly ineffective because the reducing agent is partially oxidized to additional nitrogen oxides.

As injection points are in the wall of the furnace in Area of the firebox end at certain points and / or injector lances projecting further into the combustion chamber arranged through which the reducing agent through its  Self impulse or by the impulse of an additional Carrier medium, such as. B. steam or air in the Reaction zone is introduced.

In the case of denitrification of exhaust gases, it is now necessary to apply reducing agents to the injection points, which are in the range of the optimal reaction conditions. It has already been proposed to switch the injection lances on and off individually. In addition to the local flue gas temperature, the local NO _x supply must also be taken into account, which results from the product of the local flue gas mass flow and the local NO _x concentration. However, these values cannot be measured continuously in large-scale plants. One could therefore make do with the fact that one chooses approximately only an integral flue gas temperature as a criterion for switching on injection levels or groups of injection lances.

On the other hand, it is known that a temperature measurement in the desired temperature range only for the Denitrification has the required accuracy, if Radiation influences are avoided, e.g. B. by Suction measurements. It is also known that temperatures are optical or measure acoustically. This is high technical equipment and thus subsequently high maintenance-related effort.

It is the object of the present invention to specify a method in which denitrification is carried out as a function of the measured NO concentration, taking into account changes in the local NO _x supply.

This object is achieved in that at constant Supply of the reducing agent the amount of injection points or different subsets of the injection points  predetermined partial flows of the reducing agent cyclically are applied and the NO- for each cycle step Concentration in the exhaust gas stream downstream of the injection points is measured and the injection points and / or Reductant substream distribution is determined that during the cyclical exposure to the lowest NO Has led to concentration, and then to the continuation of the Denitrification this injection and / or Partial flow distribution depending on the measured NO Concentration is applied with reducing agent, and that the optimization cycle is dependent on the change a size influencing denitrification in one specified scope and / or over a specified time is initiated automatically.

The subsets of the injection points are in terms of their Number of elements and / or the position of the elements in the Exhaust gas flow varies according to a defined sequence. The amount of injection points can also be acted upon or the loading of subsets with different partial flows of reducing agent can be varied according to a defined sequence. The too varying subsets and / or those to be varied Partial flows and the sequence of variations can be especially gained through the commissioning Experiences are determined.

The constant amount of reducing agent can simplify of the process are evenly distributed over the injection points. However, it is also possible to increase the amount of reducing agent to distribute the injection points unevenly.

Regardless of whether only the number and location of the Injection with equal distribution of the Amount of reducing agent is varied or whether in addition or the amount of reducing agent per injection point alone varies in the automatic variation cycle  a fixed sequence number, position and / or Actuation current of the individual injection points at constant total amount of reducing agent can be varied. The Injection point and / or partial reducing agent quantities distributions are compared and it becomes the Distribution recorded to the lowest NO Concentration in the clean gas leads.

The number of times during the optimization cycle continuous injection points and / or Partial distributions should be required because of the Cycle length limited to a smaller number of steps will. The order of the optimization steps and the Distributions must be started up and if necessary. at subsequent test runs and the control be entered for the cycle.

The optimization cycle is initiated automatically when the operating conditions for the selective not Catalytic denitrification to a predetermined extent and / or changed over a given time. These include e.g. B. Changes in the reference temperature at the end of the combustion chamber, Changes in the amount of steam generated, changes in Flue gas quantity, exceeding the specified Amount of reducing agent required for compliance with the required NO concentration in the exhaust gas is required or a persistent exceeding of the NO concentration in the Exhaust gas. A major advantage of the invention Standard procedure is to be seen in the fact that the procedure on Denitrification effect, d. H. on the degree of reduction of denitrification is oriented. The method is particularly suitable for Waste incineration plants, since the Reaction conditions for an SNCR process predominantly accidental and often undetectable influences are subject to because the incinerator abandoned good can change to a great extent. For the It is advantageous to conduct the procedure if  Optimization cycle as a constant amount of reducing agent in the essential those at the initiation of the optimization cycle amount supplied is used; however, it is also possible a smaller amount for carrying out the Use optimization.

It is possible that during cyclical loading the loading times for the different subsets the injection points are the same length or different. Different exposure times can arise if the measuring arrangement is able to determine that the individual NO concentration value no longer changes, and then the measurement ended.

The method according to the invention should now be based on attached figures are explained in more detail. It shows:

Fig. 1 is a schematic view of a waste incineration plant with two injection levels,

Fig. 2 is a schematic representation of various partial or subsets of individual nozzles, which are acted upon in Gleichbeaufschlagung the nozzle during an optimization cycle,

Fig. 3 is a time sequence of the addition of reducing agent and the NO concentration measurement according to the optimization cycle. Fig. 2 and

Fig. 4 shows an optimization cycle in which not the number and the position of the injection points, but the application thereof is varied.

In the waste incineration plant 1 shown schematically in FIG. 1, the waste is burned on a step grate 2 . At the upper end of the stepped grate 2 following the combustion chamber 3 4 four injection lances 5 are arranged in a first nozzle plane. At the upper end of the flue gas duct 6 following the combustion chamber 3 there is a further injection plane 7 with likewise four injection lances 5 . The position of the nozzle levels 4 and 7 is selected so that the nozzles are still in the temperature window of 700 to 1100 ° C, preferably between 850-1050 ° C. An exemplary temperature distribution is shown by the dash-dot isotherm for 900 ° C and 1000 ° C.

The injection lances 5 are connected via valves 8 to a reducing agent supply 9 so that they can be switched on and off and are controlled by a control unit 10 . For the sake of simplicity, the valve 8 and the control are shown in FIG. 1 only for one injection lance of each level.

The control device 10 is supplied with the output signal of a schematically illustrated measuring device 11 for measuring the NO concentration in the clean gas. Furthermore, the control unit can be supplied with a signal 12 corresponding to the amount of flue gas and a signal 13 corresponding to a temperature at the end of the combustion chamber. Furthermore, a signal 14 corresponding to the total reducing agent flow is supplied. A control valve 15 which adjusts the total reducing agent flow is connected upstream of the valves 8 . The control device 10 is given setpoints S 11- S 14 for the signals 11-14 and the following scheme for the subset distribution of the optimization cycle. In the following, an optimization process depending on S 11 (NO concentration) and S 14 (total amount of reducing agent) and with a sequence scheme for equally distributed lance combinations will be described. The optimization method according to the invention will now be explained with particular reference to FIG. 2.

It is assumed that the control device 10, under the guidance of the signal 11 for the NO concentration in the clean gas, acts on the nozzles 5 of the combination S identified as black circles in FIG. 2 in a uniform distribution. As can be seen from FIG. 3, the reducing agent flow increases and exceeds a predetermined value S 14 for the reducing agent flow at time t 1 . This will initiate the optimization cycle. This means that the reducing agent flow is kept constant at or slightly above the value S 14 . The control device 10 then controls the lance combinations AF one after the other in accordance with the predetermined sequence diagram, the NO concentration for the individual lance combination being measured in each case. This is identified in FIG. 3 by the letters assigned to the individual combinations. The optimization cycle ends at time t 2 . The control device compared the measured NO concentration values with one another and ascertained that the lance combination E leads to the lowest NO concentration in the exhaust gas flow. For the subsequent automatic operation, the lances of the combination E are now switched on and the control device feeds the switched-on lances 5 to the switched-on lances 5 via the control valve 15 downstream of the reducing agent supply 9 so that the specified NO setpoint is maintained. In connection with FIG. 2, an even distribution of the constant amount of reducing agent was assumed during the optimization cycle and during operation with automatic control. The number and position of the lances 5 in the individual levels 4 and 7 were varied in the optimization cycle.

However, it is also possible to maintain the number and position of the lances and not to apply them evenly. For the sake of simplicity, an arrangement with only one injection plane is shown in FIG. 4. As shown in dashed lines in FIG. 1 in connection with the nozzle plane 7 , an adjusting valve 16 would have to be connected upstream for an uneven application of each injection lance; if this also takes over the on-off function, the associated switching valve 8 can cease to exist. First, the switching state S is shown before the optimization cycle. All four injection lances are evenly distributed. In the subsequent optimization cycle, which for the sake of simplicity only comprises two cycle steps, the four lances are acted on differently:

Step A 10, 40, 40, 10% in Step B: 0, 33%, 34%, 33% and it will determine which combination is the smallest NO concentration leads. As in the introduction to the description have already been explained are also a variation of different subsets or subsets of the injection points simultaneous variation of the partial flows of the Injection points conceivable. Such combinations fall also under the present invention.

The trigger for the optimization cycle was the exceeding of the predetermined limit value S 14 of the reducing agent flow. It is conceivable that the other variables influencing denitrification mentioned in the introduction to the description trigger the optimization cycle alone, in combination with one another or in combination with the value S 14 . Exceeding the NO concentration for a predetermined period, the control device 10 derived from the measurement signal.

Claims (5)

1. A method for the selective non-catalytic denitrification of exhaust gases, in particular flue gases from waste incineration plants, in which a reducing agent is supplied to the exhaust gas stream at an exhaust gas temperature of 700 to 1100 ° C via a quantity of injection points, characterized in that with a constant supply of the reducing agent Predetermined partial flows of the reducing agent are applied cyclically to the quantity of injection points or various partial quantities of the injection points and for each cycle step the NO concentration in the exhaust gas stream downstream of the injection points is measured and the injection point and / or reducing agent partial flow distribution is determined, which is the lowest during the cyclical loading Has led NO concentration, and then these injection points and partial flow distribution depending on the measured NO concentration with reducing agent, and that the optimization cycle depending on the change e a quantity that influences denitrification is automatically introduced to a predetermined extent and / or over a predetermined time. 2. The method according to claim 1, characterized characterized in that during the Optimization cycle the supplied reducing agent the injection points is evenly distributed. 3. The method according to claim 1, characterized characterized in that during the Optimization cycle the supplied reducing agent the injection points are distributed unevenly. 4. The method according to at least one of claims 1 to 3, characterized, that during the optimization cycle as a constant The amount of reducing agent essentially at Initiation of the optimization cycle quantity supplied is introduced. 5. The method according to at least one of claims 1 to 4, characterized, that during the cyclical loading the Loading times, the individual injection points and / or reducing agent partial flow distribution is the same are long or of different lengths.