CZ92397A3 - Method and system of automatic control of combustion in a furnace - Google Patents

Abstract

In the present invention there is disclosed a method for automatic controlling combustion process in a furnace with a simultaneous measurement of free oxygen (Oi2) content and carbon monoxide (CO) content in waste gases, with defined concentration (Oi2z) of free oxygen (Oi2) determined on the base of measured and defined concentration (COiz) of carbon monoxide (CO), said method being characterized by automatic reduction of the defined concentration value (Oi2z) until equality of the carbon monoxide measured and defined concentration value (COiz) is reached. So obtained reduced defined concentration value (Oi2z) changes spontaneously by a dynamic and static concentration value ({DELTA} Oi2zd + {DELTA} Oi2zs) of free oxygen (Oi2), and this changed value is the reduced in a first defined time interval (T) by a dynamic value of concentration ({DELTA} Oi2zd) while maintain said reduced defined concentration value (Oi2z) until the end of the first time interval (T), beginning at the moment when equality of the measured and defined (COiz) concentration is reached. If, after a second time interval (T), the measured (COiz) concentration value is less than the defined one, said reduced changed defined (Oi2z) concentration value is automatically reduced unit the defined (COiz) concentration value is reached. If, after the first time interval (T), the measured (COiz) concentration value is greater that that defined, than the reduced changed defined (Oi2z)concentration value is increased by the static concentration value ({DELTA} Oi2zs) and so increased value thereof is then maintained for the second time interval (T). After lapse thereof said increased defined concentration value (Oi2z) is automatically reduced provided, the measured concentration value (COiz) does not exceed the defined one, whereby any subsequent defined time interval (T) is equal as the first time interval (T). A system for automatic control of combustion process within a furnace comprises a signal counter (3, 19) of coal conveyor belt speed, sensors (2) of measured concentration value (COiz), and path (Di22) of a defined concentration value (Oi2z) signal is connected with the path (Di222) of the (Oi2z) defined concentration variable signal via a switching system (6), whereby said path (Di222) comprises a programming device (4) having two inputs and one output connected to the input of the switching system (6), wherein said device first input (4) is connected to the sensor (2) of the measured (COiz) concentration value while the other input thereof is connected to a defined (COiz) defined concentration value post (8).

Description

(57)

The method of automated furnace combustion control comprises reducing a defined concentration of free oxygen until a defined concentration of carbon dioxide in the off-gases is reached. Thereafter, the defined concentration of free oxygen is increased, whereby, once the carbon dioxide concentration is reduced, the defined concentration of free oxygen again decreases.

AND

Method and system of automatic combustion control in a furnace

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and system for automated furnace combustion control with simultaneous measurement of free oxygen and carbon dioxide in waste gases, with a defined free oxygen concentration in waste gases based on measured, determined and limited carbon dioxide concentrations changes in fuel flow. Both the method and the system are intended for industrial furnaces, particularly in power plants in which a fuel-air mixture is burned, in particular ground coal, which is fed to the furnace by an air stream.

BACKGROUND OF THE INVENTION

From the description of Polish patent 118 383 a method of automatic combustion control is known which comprises correcting the combustion process by measuring the amount of free oxygen in the waste gases. This method assumes a constant oxygen concentration and if the measured free oxygen concentration differs from the predicted value, the ratio of fuel and air in the furnace feed mixture is changed to compare the free oxygen value to the predicted concentration value. We also know a method of automatically correcting the free oxygen content of the waste gases as a function of the performance of the object, i.e. the power of the fuel stream fed to the furnace, or the variations in the fuel calorific value. In an ideal combustion process, only carbon dioxide, free of carbon dioxide impurities, will be present in the waste gases, but no free oxygen will be present. The amount of air supplied will in this case be based on a stoichiometric calculation when combining carbon with oxygen.

In practice, however, it is impossible to achieve such a result, and therefore carbon dioxide is always found in the waste gas. In order to achieve a minimum amount of carbon dioxide in the waste gases, an additional amount of oxygen is supplied to the furnace. Increasing the amount of air, however, considers losses in the chimney, resulting in an increase in the amount of waste gases and an increase in the amount of heat escaping through the chimney into the atmosphere. In practice, therefore, there must be a compromise in the composition and amount of waste gases. This means that a certain amount of carbon dioxide must be allowed and the amount of air used must be such that the amount of carbon dioxide in the waste gases is not too large with a small amount of air. The amount of supply air is determined by measuring the amount of free oxygen in the waste gases. In the known methods of combustion control, a limited minimum concentration of free oxygen in the waste gases is assumed for the experimentally selected objects. The limited maximum concentration of carbon dioxide is set not only with regard to losses due to insufficient combustion, but also with regard to the harmful effect of carbon dioxide on the environment.

Even if the amount of carbon dioxide emitted into the atmosphere could be higher for economic reasons, gas emissions must be limited for environmental reasons. The limiting minimum concentration of free oxygen is defined with respect to losses due to incomplete combustion and loss of thermal energy transfer in the stack, but also to the amount of oxygen and nitrogen components in the waste gases. These components are particularly hazardous to the environment and therefore their emissions are limited. In an effort to limit the amount of nitrogen oxide, it is necessary to limit the supply of oxygen for combustion and thus the amount of free oxygen in the waste gases, although this is achieved at the cost of increasing the concentration of carbon dioxide. Polish patent 156 836 discloses a system for automatic optimization of the combustion process in a thermal object having sensors sensitive to the concentration of free oxygen in the waste gases, which sensors are connected to the inlet of the regulator and its outlet to the fan of secondary air supply to the furnace.

The purpose of the present invention and the system which optimizes the combustion process such that at an average concentration of carbon oxides in the off-gas that does not exceed a limiting set concentration, the air supply to the furnace is minimized, thereby reducing stack losses and facilitating the reduction process atmosphere in the waste gases.

This is achieved by automatically reducing the defined value of the concentration of free oxygen in the waste gases until the desired concentration of carbon dioxide in the waste gases is equal to the defined, limiting and permitted concentration of the chemical components. When this condition is reached, the defined value of free oxygen concentration is increased by a step increase by static and dynamic value. After the time Τθ has elapsed, the defined oxygen concentration decreases the dynamic value, which is maintained until the end of the defined time period T. For the specified time period T the concentration of oxygen oxide in the waste gases is greater than the defined and allowed concentration, the defined instantaneous value of free oxygen in the waste gases is increased by its static value, which is maintained for another defined time period T. the concentration of carbon dioxide in the waste gases is less than the defined allowable concentration, then the defined free oxygen concentration value is automatically reduced. The reduction of the defined free oxygen concentration is carried out linearly.

The system of the present invention has a defined free oxygen concentration signal path coupled to a defined free oxygen concentration signal path in the waste gases, and a switchable system is used for this purpose.

The variable path value signal of the defined free oxygen concentration in the off-gas includes a programming device whose output is connected to the inlet of the switching system, one input is connected to the carbon dioxide sensor in the off-gas, another input with a signal from the defined carbon dioxide concentration. Said programming device has a program for realizing a method of automatic control of the combustion process.

Overview of the drawings

The embodiment of the invention, in the following example, will be described simultaneously with reference to Fig. 1, and the system of the invention with reference to Fig. 2.

DETAILED DESCRIPTION OF THE INVENTION

Example of application of the method

For the selected object, an experimental, minimum and defined concentration of free oxygen in waste gases of 0 = 1.8% was assumed, with a maximum defined concentration of carbon dioxide

_From C0 = 24 mg / m ³ present in the exhaust gases. It was found that with a defined concentration _of carbon dioxide C0 = 24 mg / m ^3, the content of nitrogen oxides has permitted level of 460 mg / m ^3, in the whole managed object region. A predefined time was assumed

In addition, the dynamic value of the defined free oxygen concentration at? 0.2 = 0.2% and the static value of the defined free oxygen concentration at _? 2 _zs = 0.23% were determined experimentally. It was assumed that a defined linear decrease the concentration of free oxygen will take place with speeds up to _2z / dt = 0.25% O ^ / hr. At time 0 (Fig. 1), the carbon dioxide concentration in the off-gas is much lower than the defined CO concentration. Defined free oxygen O concentration in waste gases decreases linearly with velocity d0 ^ / dt = 0.25%

As a result, the concentration of carbon dioxide in the off-gases is increased, reaching at a point I the value of a defined CO concentration. At this point, the defined 2 concentration of free oxygen increases from the value at time I by a concentration value δο +40 = (0.23 + 0.2)%. Terms

2 from 2 of inactivity of the object, the concentration of oxide in the waste gases increases. During the observed time T _d , the defined free oxygen concentration is constant, but after T _q this value decreases to the value at time I, increased by a static value of AO = 0.23% and remains at the same value unchanged until time II, until after a defined time period T. If the time II, the concentration of carbon dioxide in the waste gas is still greater than the defined C0 _of defined concentration of free oxygen in the exhaust gases is increased by further ^^^ ^ O = 0.23%. The defined time period T is measured simultaneously. After T at III, the carbon dioxide concentration is less than the defined CO concentration. This starts the linear decrease defined from

free oxygen concentration O _2z - If found that when carbon dioxide concentration III did not decrease, relative to a defined concentration _of C0, there would rise III the moment a defined concentration of free oxygen ^ 0 for another static hodnotuůO _AZS = 0.23%. In the example, the condition of carbon dioxide concentration which is lower than the defined concentration _of C0, the drop in defined concentrations of free oxygen until the IV, the carbon dioxide concentration again reached the value defined by the concentration _of CO. The same activity as between I and II occurs. After time T, at time V, the concentration of carbon dioxide is lower than the defined concentration of CO 2, while still showing a decreasing tendency. This begins a linear decrease in the defined concentration of free oxygen in the waste gases. Method of combustion according to this method causes undulating motion concentration of carbon dioxide in waste gases around a defined value _of the CO concentration. Assumed parameters for a given object are searched so that the average concentration of carbon dioxide is not greater than the defined concentration of CO over a longer period of time.

From section. The amount of air supplied to the furnace during this time is less than maintaining a defined concentration of free oxygen in the waste gases unchanged, which is set to a defined concentration of CO. How was it

In practice, the concentration of nitrogen oxides was maintained at a level not exceeding 460 mg / m ^{3 of} waste gases.

The automatic combustion control system has a signal path D for changing the total air volume, wherein said path D is connected to a ventilator air outlet control system (not shown in FIG. 2). The path fi is connected to the output of the counter 14, one input of which is connected to the signal counter 3, where the signals come from the rotary sensors 8 of the conveyors to all mills (crushers) which are also not shown. The second input of the counter 14 is connected to the path P ₂ of the total air change signal, which depends on the concentration of free oxygen and carbon dioxide in the waste gases. The path fi ₂ is connected to the output of the master control 12. One of the master 12s is connected to the path D of the free oxygen signal in the waste gases, said path fi being connected via the switching system 13 to the free oxygen sensors 11 in the waste gases. in the waste gas stream. The second output of the master controller 12 is coupled to signal path ₂₂ defined fi 0 _2z concentration in the waste gases. The path fi ₂₂ is connected to a system 7 of a minimally defined concentration of free oxygen in the waste gases. The inlet of the system 7 is connected to the outlet of the switching system 6 at the switching station 5. One of the inputs of the switching system 6 is connected via path ₂₂₁ to the station 1 to define a constant concentration of free oxygen in the waste gases.

The second input of the switching system 6 is connected via path 22 -2 P ^ro 9 ^raniovac and ^his device 4, which includes the program changes defined by the concentration of free oxygen _{ζ =} 0 in the waste gases, depending on the carbon dioxide concentration in the exhaust gases in terms of a defined value carbon dioxide concentration. One of the inputs of the programming device 4 is connected to the oxygen concentration sensor 2 in the waste gases, the other is connected to the station 9 of the defined value C0 _of

At site 1 to define the value of free oxygen concentration in the waste gases, the free oxygen concentration was defined to be 0 _2z = 1.8%. The signal from the station 1 passes through the switching system 6 to the system 7 of the minimum concentration of free oxygen in the waste gases. If the signal from site 1 determined a lower value of free oxygen concentration than the minimum value, the system 7 would send a signal of said minimum value via path D to the master controller 12. If the defined free oxygen concentration exceeds the minimum free oxygen concentration value, the entire value signal would be transmitted to the master controller 12. The two signals from paths D and D ₂₂ are compared in the master controller 12. If the signal coming from the sensors 11 shows a lower concentration If the oxygen concentration in the exhaust gas is higher than the defined concentration of 0, the higher-level control transfers it to the counter 14 and further to the fan to increase the amount of air supplied to the value at which the signals will equal each other. If the signal from the sensors 11 indicates that the free oxygen concentration in the waste gases is greater than the defined _O2z concentration, the control 12 sends a signal to the fans to reduce the amount of air supplied to a value at which the signals will equal each other. The free oxygen in the waste gases drops. The signal coming from the master control 12 to the counter 14 is added to the signal passing along the path D from the counter of the coal conveyor speed, which signal is proportional to the fuel flow to the furnace. If a change in the amount of fuel flow is detected, a signal is sent to the fan to change the amount of supplied air. At the site 5, the system 6 can be switched and the path is connected to the programming device 4 or to the manual definition site 0-2 of

The programming device 4 changes the defined concentration of free oxygen according to the program fulfilling the task of the automatic control method according to the invention. The signal coming from the programming device 4 to the master control 12 is compared with the signal coming to the control 12 from the sensors 11. The control 12 and the counter 14 operate as described in the case of connecting the system 1, i.e. with a fixed amount defined concentration of free oxygen in waste gases.

The counter 14 allows control of the ratio of the total amount of air in the fuel stream supplied to the furnace when the control 12 is switched to manual control, for example when the sensors 11 measure the quantity 0.

Claims (5)

PATENT REQUIREMENTS>>> 1. An automated furnace combustion control system with simultaneous measurement of the free oxygen and carbon dioxide content of the waste gases, with a defined free oxygen concentration in the waste gases determined on the basis of the measured, determined and limited carbon dioxide concentration, is characterized by The amount of oxygen (O) in the waste gases is automatically reduced until the amount of carbon dioxide concentration in the waste gases is equal to the amount of the defined limiting concentration of carbon dioxide (CO 2). 0 / changes by a jump of dynamic and static value ()) + OO /, when this value alternately after a defined time period (T) decreases to a static value (aO ^) of free oxygen concentration, and when this static value (α0 _2ζώ ) maintains a defined time period until the end dy (T), which starts at the moment when the concentration of carbon dioxide in the waste gases reaches the defined limiting concentration of carbon dioxide (CO), and if after a defined time (T) the concentration of carbon dioxide in the waste gases is lower than the defined permitted concentration , defined by the value of the concentration of free oxygen / 0 _2z / in waste gases is automatically reduced until the defined allowable concentration of carbon dioxide / C0 _of /, and if after a period of time / T / concentration of carbon dioxide in the exhaust gas larger than the defined allowable concentration free oxygen (CO), then the defined value of free oxygen (0) in the waste gases is increased by the static value of the oxygen concentration A2 _{2zs /} ^and maintains this free oxygen concentration for the following period (T), oxygen / Q / · Method according to claim 1, characterized in that the automatic reduction of the defined value of the concentration of free oxygen (O) in the waste gases is carried out linearly. Method according to claim 1, characterized in that the automatic decrease of the defined value of the concentration of free oxygen (2) in the waste gases is performed exponentially. Method according to claim 1, characterized in that the change in the defined value of the oxygen concentration (0 _2e ) by a jump of static (50 _{° C} ) and a dynamic (50 _{° C} ) value is maintained by the selected time period (T 2) and at this time period, the value is decreased by the dynamic value of% Q _22ea / free oxygen. 5. Automatic furnace combustion control system taking into account the measured values of free oxygen and carbon dioxide in waste gases with a defined free oxygen concentration, the system comprising a coal conveyor speed signal counter, exhaust gas carbon dioxide sensors, characterized by: that is connected to the path / Q ₂₂ / defined by the concentration of free oxygen / Q _{23 =} I / drain path / D _S22 / signal with the variable value defined by the concentration of free oxygen / 0 / and uses switching system / 6 /, while the path a / D ₂₂₂ (a signal of variable value of defined free oxygen concentration) includes a programming device (4), the output of which is connected to the input of the switching system (6), one input is connected to the carbon dioxide sensor (2) in waste gases, the other output is connected to a defined carbon dioxide concentration (9)