DE102008056676A1 - Method and device for monitoring the combustion of a power plant by means of a real concentration distribution - Google Patents

Abstract

In a method for monitoring the combustion in a combustion space of a power plant and an associated device, a real concentration distribution of a first substance in the combustion space is determined and the concentration distribution of a second substance is determined on the basis of the real concentration distribution of the first substance and at least one physical model equation.

Description

The The invention relates to a method and a device for monitoring the combustion in a combustion chamber of a power plant, in particular of a coal-fired power plant where, among other things, it is a real one Concentration distribution of a first substance in the combustion chamber is determined.

at Power plants, it is the basic goal in a combustion chamber of the power plant, for example a boiler with a square base of 10 meters by 10 meters, combustion possible to monitor extensively, to derive the necessary quantities for the optimization to derive the combustion process.

So is known as the method of absorption spectroscopy. As alternative Measurement technology is known as sonic pyrometry. With absorption spectroscopy or sound pyrometry can only mean values of a line measured in the boiler room or combustion chamber become.

To the Calculate the temperature and concentration distribution in one Plane of a combustion chamber from measured averages at different Setting the combustion chamber of a power plant is the CAT measuring technology, the computer aided tomography, known.

It An object of the invention is a more extensive monitoring to allow combustion in a power plant, thereby laying the foundation for optimization to deliver the combustion process.

The Task is according to the invention with a method according to claim 1 and a device according to claim 9 solved. Before some refinements are described in the dependent claims.

The inventive method to monitor the combustion in a combustion chamber of a power plant, in particular of a coal-fired power plant, involves the steps of: determining a real Concentration distribution of a first substance in the combustion chamber and determining the concentration distribution of a second substance based on the real concentration distribution of the first substance and at least a physical model equation. The device according to the invention to monitor the Combustion in a combustion chamber of a power plant, in particular a coal power plant, comprises means for determining a real concentration distribution of a first substance in the combustion chamber and means for determining the concentration distribution a second substance based on the real concentration distribution of the first substance and at least one physical model equation.

Of the The basic idea of the invention, in other words, is that while combustion in a power plant a concentration distribution of a given substance (the so-called second substance) a combination of the known concentration distribution of another Stoffes (the so-called first substance) and physical laws can be determined. So it is possible to or detectable concentration distribution of a substance, in particular of a gas, based on this approach as far as possible close to reality. With the solution according to the invention can not just an almost complete one Image of combustion being generated in a boiler of a power plant but this generation is largely based on the real situation of ongoing operations. It is being real Input variables assumed and not built solely on a simulation. In addition, physical Regularities, like they could also be used in a simulation, Concentration distributions of substances for the further optimization of the Harnessing combustion that has not previously been measured could.

at In the above definition of the invention, "material" generally refers to any type of combustion and / or product understood, especially in the form of gas as a component the exhaust gas.

at a first advantageous embodiment of the method according to the invention The at least one physical model equation forms the kinetics in the combustion chamber.

at a second advantageous embodiment of the method according to the invention The at least one model equation forms the diffusion in the combustion chamber from. Diffusion is a physical process leading to an even distribution of particles and thus complete Mixing two substances leads. Diffusion is based (in contrast to the flow) on the thermal proper motion of particles. The particles may be atoms, molecules or charge carrier act. With uneven distribution statistically, more particles move from areas high to areas less Concentration or particle density as the other way around. This will be net a macroscopic mass transport causes.

In a third advantageous development of the method according to the invention, the real concentration distribution of the first substance is determined in at least one plane. It is so on min at least a two-dimensional or 2D distribution of the concentration of the first substance constructed in order to map the concentration distribution of other substances taking into account physical laws in the boiler. Such 2D distributions can be imaged with the above-described, already known measurement methods with high measurement accuracy.

at a fourth advantageous embodiment of the method according to the invention a temperature distribution in the combustion chamber is determined. The temperature distribution is for the determination of the concentration distribution of the first substance is used, as well as in the determination of the physical considered according to the invention laws as well as their parameterization.

at a fifth advantageous development of the method according to the invention, the temperature distribution using a combination of absorption spectroscopy and CAT metrology determined. CAT is the abbreviation from computer aided tomography and poses in medical technology a standard method with which it is possible to have a two-dimensional Determine temperature distribution.

at a sixth advantageous development of the method according to the invention is the concentration distribution of the second substance in at least of a level. The 2D detection can be realized with reasonable computertechnischem effort. Furthermore possible do a good approximation by layering the 2D layers Illustration of the associated To generate concentrations in the three-dimensional combustion chamber.

In a seventh advantageous development of the method according to the invention, the concentration of the second substance at a point in the combustion chamber is determined as a function of the temperature or the temperature distribution at other locations and of the concentration or concentration distribution of the first substance at other locations. The function may be as follows, for example:

c (NO _x ) at the point x, y, z
= f (temperature distribution in all other places, c (O ₂ ) distribution in all other places),

where c (NO _x ) represents the concentration of NO _x (nitric oxide), f stands for the function itself and c (O ₂ ) represents the concentration of O ₂ (oxygen).

With the procedure according to the invention, it is possible to obtain an almost complete picture of a combustion and thus be able to better regulate this combustion. Physical relationships are used according to the invention to generate additional information in addition to real measurement results. For example, it can be determined how nitrogen oxide gases are distributed in the combustion chamber in order to generate more accurate information about the combustion process and to be able to regulate this situation-related. As input values for the process according to the invention, the concentrations of O ₂ (oxygen), CO (carbon monoxide) and CO ₂ (carbon dioxide) are in particular preferably measured in real terms.

The mentioned advantageous developments of the method according to the invention are preferably in the form of appropriately adapted facilities as well in the device according to the invention realized.

following is an embodiment of solution according to the invention the attached schematic drawings closer explained. It shows:

1 an embodiment of the device according to the invention and

2 an embodiment of the method according to the invention.

In 1 is a combustion chamber 10 a coal power plant, not further illustrated, in which a coal fire burns during operation of the coal power plant. In the combustion chamber 10 Here are the fuel coal with associated fuel gases, flames 11 as well as exhaust gases.

In the combustion chamber 10 are two levels of measurement 12 and 14 provided at the edge of each measuring instruments 16 are located. Two of each measuring instruments 16 allow a linear measurement in the associated measuring plane 12 respectively. 14 , using the measuring instruments 16 and an associated evaluation device 18 the concentrations of the substances O ₂ (oxygen) and CO (carbon monoxide) can be measured. Furthermore, with the measuring instruments 16 and the evaluation device 18 the temperature distribution in the associated measuring plane 12 respectively. 14 be determined. The measurement is based on a combination of absorption spectroscopy and the CAT technique.

The evaluation device 18 is via a data bus 20 with an optimization device 22 , an operating device 24 and a guide or Leittechnik 26 operationally coupled. About the operating device 24 are those of the evaluation 18 determined real concentration distributions and temperature distributions used in such a way that with the optimizer 22 Suggestions for optimizing the combustion he puts and this in the guide 26 can be used. As a result, in the combustion chamber 10 burning flames 11 optimized especially with regard to a low emission of NO _x (nitric oxide).

For optimization uses the optimizer 22 Here, physical model equations of diffusion and kinetics in the combustion chamber, previously based on a model of the combustion chamber 10 created and in the optimizer 22 have been stored.

The associated method is in 2 illustrated. It includes the step 28 the establishment of physical model equations of combustion in the combustion chamber 10 as well as further steps 30 . 32 and 34 , In step 30 is the concentration distribution of at least the substances O ₂ and CO in the above measurement levels 12 and 14 determined. In step 32 the temperature distribution in these levels is determined.

These input data are in step 34 used to the concentration distribution of another substance, in this case in particular NO _x , not only in the measurement planes 12 and 14 but also in the remaining areas of the combustion chamber 10 to investigate. If necessary, conclusions can be drawn in this step 34 as well as from the steps 30 and 32 used to step the formation of the physical model equations 28 continue to improve.

Based on this determination then takes place in one step 36 an optimization of the combustion, for example by a change in the air stratification and / or a sectional change in the excess air.

Claims (9)

Method for monitoring combustion in a combustion chamber ( 10 ) of a power plant, in particular a coal-fired power plant, comprising the steps of: - determining ( 30 ) a real concentration distribution of a first substance in the combustion space and - determining ( 34 ) of the concentration distribution of a second substance on the basis of the real concentration distribution of the first substance and at least one physical model equation. Method according to Claim 1, in which the at least one physical model equation contains the kinematics in the combustion chamber ( 10 ) maps. The method of claim 1 or 2, wherein the at least one model equation, the diffusion in the combustion chamber ( 10 ) maps. Method according to one of claims 1 to 3, wherein the real concentration distribution of the first substance in at least one level ( 12 . 14 ) is determined. Method according to one of claims 1 to 4, wherein a temperature distribution in the combustion chamber is determined ( 32 ). Method according to claim 5, wherein the temperature distribution using a combination of absorption spectroscopy and CAT metrology is determined. Method according to one of claims 1 to 6, wherein the concentration distribution of the second substance in at least one plane ( 12 . 14 ) is determined. Method according to one of claims 1 to 7, wherein the concentration of the second substance at a location in the combustion chamber as a Function of the temperature in other places and of the concentration of the first substance at other points. Device for monitoring combustion in a combustion chamber ( 10 ) of a power plant, in particular a coal-fired power plant, comprising: - a facility ( 16 ) for determining a real concentration distribution of a first substance in the combustion chamber ( 10 ) and - an institution ( 18 ) for determining the concentration distribution of a second substance on the basis of the real concentration distribution of the first substance and at least one physical model equation.