RU2156155C2 - System for automatic control over process of cleaning of combustion products from nitrogen oxides with limitation of concentration of ammonia in cleaned gases - Google Patents

Abstract

FIELD: automation of processes of chemical cleaning of combustion products from nitrogen oxides. SUBSTANCE: system include nonlinear elements that accounts for functional dependence between load and gross effluent of NO_x. It is placed between actuating controller of reagent feed and transducer of signal of load of boiler. Key correcting controller is connected via adder to transducer of signal of concentration of NO_x in cleaned gases and to nonlinear element. Source of additional correcting signal is manufactured in the form of additional correcting controller linked to transducer of concentration of NH₃ in cleaned gases. One input of two-position switch is connected to output of key correcting controller and its other input is linked to output of additional correcting controller, output of switch is connected to actuating controller. Switching-over element of switch is connected to relay element with one operational setting to connect additional correcting controller to actuating controller when concentration of NH₃ in cleaned gasses reached limiting value and to connect key correcting controller when concentration of NH₃ in cleaned gases decreases to permissible level. EFFECT: enhanced efficiency of automatic control over process of cleaning of combustion products from nitrogen oxide with effective limitation of overshoot of ammonia. 1 dwg

Description

 The invention relates to the field of chemical purification of combustion products and can be used to automate the process of their purification from nitrogen oxides by non-catalytic reduction of the latter with a reagent in the form of ammonia or compounds that form ammonia during thermal decomposition.

The closest to the essential features of the analogue (prototype) of the invention can serve as a known system for the automatic cascade control of the process of purification of combustion products from nitrogen oxides (NO _x ) in the boiler furnace, carried out by non-catalytic reduction of NO _{x with a} reagent in the form of ammonia (NH ₃ ) or compounds, forming NH ₃ during thermal decomposition, containing an executive regulator of the reagent supply, connected to the signal sensor for the boiler load and the signal sensor for reagent consumption, the main corr a projection regulator for limiting NO _x in the purified gases, a source of an additional correction signal for limiting the breakthrough of NH ₃ into the purified gases, a switch for stepwise adjustment of the correction signal and a nonlinear element [1]. In this system, the source of an additional correction signal to limit the breakdown of NH ₃ generates this signal based on its empirical dependence on the load of the boiler at various temperature ranges of gases in the reaction zone of the interaction of NH ₃ with NO _x which change by dosing the reagent to the corresponding flue levels. The switch is installed on the line of action for an additional correction signal of the averaged temperature for all reagent dosing levels for stepwise control of the scale of the acting signal depending on the load, reagent consumption and return signal according to the resulting value of the temperature effect. In this case, an additional correction signal to limit the breakthrough of NH _{3 is} added to the signal from the main correction regulator by limiting NO _x and is supplied with it to the input of the executive regulator.

The main disadvantage of this solution is the weak influence of the correction signal on the NH ₃ breakthrough, since under all conditions the main corrective control signal remains the NO _x concentration signal in the purified gases, which continues to affect the reagent supply regulator (ammonia water) even after reaching the maximum permissible NH breakthrough ₃ . At the same time, ammonia, interacting with sulfur trioxide SO ₃ present in gases, leads to the deposition of ammonium salts on the boiler’s air heater, which significantly impairs its performance. In addition, ammonia itself is quite toxic, and therefore its release into the environment should be limited. An additional corrective action to limit the breakdown of NH ₃ in the known system is not carried out directly, but according to indirect indicators, which complicates the scheme and does not provide sufficiently reliable results.

 The achieved result of the invention is to increase the efficiency of automatic control of the process of purification of combustion products from nitrogen oxides while effectively limiting the breakthrough of ammonia.

This is ensured by the fact that in the system of automatic cascade control of the process of purification of combustion products from nitrogen oxides (NOx) in the boiler furnace, carried out by non-catalytic reduction of NO _{x with a} reagent in the form of ammonia (NH ₃ ) or compounds forming NH ₃ during thermal decomposition containing reagent supply controller connected to the sensor signal for the boiler load and the sensor signal the flow rate of the reagent, the main adjustment knob for limiting NO _x in the purified gas, a source of additional armature projected onto the signal for limiting slip NH ₃ in purified gases, a switch for a step change of the correction signal, and a nonlinear element according to the invention, the nonlinear element is designed taking into account the functional dependence between the load and gross ejection of NO _x and located between the actuating reactant supply controller and the sensor signal on the boiler load, correcting the main controller through the adder is connected to the sensor signal for NO _x concentration in the treated gases and the nonlinear element, a source of additional Yelnia correction signal is in the form of additional correction controller connected to the sensor concentration of NH ₃ in the treated gases, a switch is made two-position, its one input connected to the output of the main correction controller, the other - to the output of the additional correction controller switch output - to an actuator controller, and the switching element of the switch is connected to the relay element having the operation settings for connecting an additional regulator a corrective regulator when the limit value of the concentration of NH ₃ in the purified gases is reached, and the main corrective regulator when the concentration of NH ₃ in the purified gases is reduced to an acceptable level.

 The drawing schematically shows a diagram of the proposed automatic control system.

It contains an executive regulator 1 for supplying a reagent connected to a sensor 2 for signaling the load of the boiler and a sensor 3 for signaling for a flow of reagent, the main correction regulator 4 for restricting NO _x in the purified gases, a source of an additional correction signal for limiting the breakthrough of NH ₃ in the purified gases, and a switch 6 to step change the correction signal. The main correction controller 4 is connected to the sensor 5 of the signal according to the concentration of NO _x in the purified gases and the sensor 2 of the signal according to the load of the boiler. The source of the additional correction signal along the NH ₃ slip is made in the form of an additional correction regulator 7 connected to the sensor 8 for the concentration of NH ₃ in the purified gases. The load signal sensor 2 is connected to the regulators 1 and 4 through a non-linear element 9, which takes into account the functional relationship between the load and the gross emission of NO _x . The switch 6 is made on-off, one of its input 10 is connected to the output of the main correction controller 4, the other 11 to the output of the additional correction controller 7 to limit the breakthrough of NH ₃ , the output 12 of the switch to the executive controller 1, and the switching element 13 of the switch is connected to the relay element 14, having the response settings for connecting to the executive regulator 1 additional corrective regulator 7 when the limit value of the concentration of NH ₃ in the purified gases and the main corrective regulator 4 while reducing the concentration of NH ₃ in the purified gases to an acceptable level. The output of the nonlinear element 9 and the sensor 5 for the NO _x concentration signal in the purified gases are connected to the main correction regulator 4 through the adder 15. The output of the executive regulator 1 is connected to the mechanism for changing the passage section of the valve 16 on the reagent supply line 17 to the boiler furnace (not shown ) Executive controller 1 and corrective controllers 4, 7 are equipped with adjusters 18, 19, 20, respectively, of the controlled values of the adjustable parameters.

 The operation of the automatic control system is as follows.

In the main mode, the executive controller 1 acts on the mechanism for changing the flow area of the valve 16 under the influence of three signals: the signal from the sensor 2 for the boiler load, converted with the help of a nonlinear element 9 into a signal proportional to the gross emission of NO _x , the feedback signal from the sensor 3 for consumption the reagent and the signal from the main correction controller 4, which maintains the gross emission of NO _x within the given limits. An additional corrective regulator 7 to limit the breakdown of NH ₃ in this mode of operation of the executive regulator 1 is disabled, but the sensor 8 of the concentration of NH ₃ in the purified gases through the relay element 14 has a parallel connection with the switching element 13 of the switch 6. Upon reaching the maximum permissible concentration of NH ₃ relay element 14 rearranges the switching element 13 from input 10 to input 11 with the transfer of the Executive controller 1 to a signal from an additional correction controller 7. Moreover, regardless of the shafts reagent NO _x regulation of the supply of the reagent is carried out only on the condition of the inadmissibility of exceeding the limit value of the leakage into the environment NH ₃ more toxic than NO _x . After reducing the concentration of NH ₃ in the purified gases to a predetermined allowable value, the automatic regulator 1 is automatically switched to work with the main correction signal according to the mode of maintaining the gross NO _x emission within the given limits.

Sources of information
1. Von N.-N. Voje, B. Fisher, G. Mittelbach. Inbetrriebnahne-und Betriebserfahrungen mit SNCR-Anlagen an Shmelzfeuerungskesseln.- VGB Kraftwerkstechnik 71 (1991), Heft 10, c. 949, Fig. 8.

Claims (1)

A system for the automatic cascade control of the process of purification of combustion products from nitrogen oxides (NO _x ) in the boiler furnace, carried out by non-catalytic reduction of NO _{x with a} reagent in the form of ammonia (NH ₃ ) or compounds forming NH ₃ during thermal decomposition, containing an executive reagent supply regulator connected with a signal sensor for boiler load and a signal sensor for reagent consumption, the main correction regulator for limiting NO _x in purified gases, the source of an additional correction signal for the reduction of the NH ₃ slip into the cleaned gases, a switch for stepwise changing the correction signal and a non-linear element, characterized in that the non-linear element is made taking into account the functional relationship between the load and the gross emission of NO _x and is located between the executive reagent supply regulator and the signal sensor for the boiler load, the main adjustment knob through an adder coupled to the sensor signal for NO _x concentration in the treated gases and the nonlinear element, a source of additional corrective B Nala is designed as a further correction controller connected to the sensor concentration of NH ₃ in the treated gases, a switch is made two-position, its one input connected to the output of the main correction controller, the other - to the output of the additional correction controller switch output - to an actuator controller, and the switching element the switch is connected to the relay element having the settings of the response to connect to the Executive regulator additional corrective regulator p and the limit value NH ₃ concentration in the purified gases and a basic correction controller while reducing the concentration of NH ₃ in the purified gases to an acceptable level.