EP2315974A2 - Device and method for controlling the fuel-air ratio during the combustion of ground coal in the firing system of a coal power plant - Google Patents

Abstract

The invention relates to a device and method for controlling the fuel-air ratio during the combustion of ground coal in the firing system of a coal power plant, which comprises means for the pneumatic delivery of ground coal to the burners of the firing system of the coal power plant and means for feeding combustion air to the burners or into the firing chamber of the firing system of the coal power plant and in which the amount of combustion air and the amount of carrier air is controlled. The aim of the invention is to achieve a high reliability of the control combined with low maintenance of the air mass measurement devices for measuring the amount of combustion air and carrier air. According to the invention, this aim is achieved by a measurement device for measuring the amount of combustion air which, according to the correlation measurement method, evaluates the triboelectric effects on sensors which are arranged in series in the direction of flow of the combustion air and thus measures the flow velocity of the combustion air. To this end, between 0.1 mg and 10 mg of fine-grained particles having a particle diameter of between 20 μm and 200 μm are introduced per m³ air into the suctioned fresh air. The introduction of particles into the suctioned fresh air is carried out essentially during the starting phase of a firing system of a coal power plant. The measurement of the amount of carrier air is preferably carried out by means of a correlation measurement device that evaluates the triboelectric effects on sensors which are arranged in series in the carrier air stream in the direction of flow of the carrier air.

Description

 Apparatus and method for controlling the fuel-to-air ratio of pulverized coal in a coal fired power plant

The invention relates to a device for controlling the fuel-air ratio in the combustion of milled coal in a coal-fired power plant, the means for pneumatically conveying the ground coal to the burners of the coal-fired power plant and means for supplying combustion air to the burners or in the Has combustion chamber of the coal-fired power plant, the power plant in the direction of flow of the air has at least the following facilities:

A fresh air fan for sucking in fresh air from the environment, a mill fan for promoting a portion of the fresh air sucked in as air for loading with ground coal, a regenerative air preheater for preheating the fresh air sucked in and part of the carrying air using the flue gas heat of the coal fired plant firing system, wherein a Storage mass of the regenerative air preheater, usually smooth or corrugated sheets, alternately heated by the hot flue gas and then cooled by the fresh air or the carrying air, an air quantity control device for controlling the combustion air introduced into the firebox, a Luftmengensteuereinrich- device for controlling the pneumatic Promotion of ground coal to be used carrying air and measuring equipment for measuring the introduced into the coal-fired power plant combustion chamber amount of combustion air and means for metered supply of a preselected amount Meng e of ground coal to the burners. The invention further relates to a method for controlling the fuel-air ratio in the combustion of milled coal in a coal-fired power plant having at least the features listed above.

The control of the fuel-air ratio in the combustion of milled coal in coal fired power plants comes to achieve a substantially complete combustion of the fuel supplied or to maintain a predetermined stoichiometry of the combustion process and thus to achieve a high energy efficiency and compliance with low emissions a special Meaning too. Combustion systems in coal power plants therefore have, in addition to suitable means for the metered supply of a preselected according to the requested load amount of fuel to the burners control means with which the burners or the firebox supplied combustion air in function of the supplied Fuel quantity is controlled. For this purpose, measuring devices are required by means of which the introduced into the firebox combustion air quantity can be detected as accurately as possible metrology. Both are necessary in order to optimally regulate the combustion process in dependence on the load, wherein the quantity of fuel is preselected in accordance with the demanded load and the quantity of combustion air is controlled in order to achieve a predetermined stoichiometry of the combustion. In practice, both coal fired power plants are found where each burner or group of burners is supplied with a preselected amount of ground coal and, in accordance with this preselected amount of ground coal, the amount of combustion air supplied to that burner or group of burners to achieve a predetermined stoichiometry Combustion is controlled, as well as firing systems in which only the total amount of all burners of a boiler supplied amount of ground coal is selected and, accordingly, only the total of all burners this boiler or the boiler total supplied amount of combustion air is controlled.

In any case, it is necessary to measure the amount of combustion air either with respect to a single burner or a group of burners or all burners of a boiler or the boiler as a whole in order to realize the corresponding control (s) of the amount of combustion air and so on to regulate the combustion process.

Furthermore, in power plant combustion systems with pneumatic conveying of the ground coal to the burners, the carrying air quantity for the pneumatic coal transport is controlled. This control also requires a metrological detection of the carrying air quantity.

Almost exclusively in coal-fired power plants, the air flow measurement using pressure measuring probes by means of differential pressure measurement. For this purpose, the pipe or duct system carrying the combustion air and the pipe or duct pressure measuring probes carrying the carrying air are installed in each case. Based on the measured pressures, the flow velocity in the channels can be determined and the respective air quantity can be determined by taking into account the channel geometry. Preferably, the pressure probes are not directly in the channel cross-section, but are connected via so-called impulse lines with the air-carrying channels. To improve the energy efficiency of a power plant combustion system, it is customary to preheat the fresh air by a storage mass, usually smooth or corrugated sheets, a regenerative air preheater alternately heated first by the hot flue gas and subsequently from the fresh air is cooled, so that a heat transfer from the flue gas takes place on the fresh air. Connected with this is the entry of fly ash particles in the fresh air. When operating a power station this regularly leads to contamination of the pressure probes or the impulse lines. Continuous cleaning and maintenance are the result. The problem is that the degree of contamination of the pressure probes can not be determined clearly based on the measured differential pressures and therefore the measurement results are subject to a considerable risk of error as the operation progresses. A drifting of the air flow measurement, which can only be determined with great effort, is the result. Ultimately, this leads to an inaccurate control of the fuel-air ratio, combined with a deteriorated efficiency and increased pollutant emissions.

The aim of the invention is a device and a method for controlling the fuel-air ratio in the combustion of milled coal in a coal-fired power plant, which are characterized by a high reliability with low maintenance. This entails the task of developing a drift-free air flow measurement in coal-fired power plant furnaces.

This object is achieved with a device according to the first claim and a method according to the eighth claim. In the related to the first claim claims 2 to 7 advantageous embodiments of the device according to the invention are described in the claims related to the 8th claim 9 to 13 advantageous embodiments of the inventive method.

A device according to the invention for controlling the fuel-air ratio in the combustion of milled coal in a Kohlekraftwerksfeuerungsanla- ge, the means for pneumatically conveying the ground coal to the burners of the coal plant firing system and means for supplying the combustion air to the burners or in the firing of Has coal combustion plant, wherein in the flow direction of the air at least the following facilities are arranged, a fresh air fan for sucking fresh air from the environment, a mill fan for promoting a portion of the fresh air sucked as carrying air to coal mill, a regenerative air preheater for preheating the fresh air sucked and a part the carrying air using the flue gas heat of the furnace, wherein a storage mass of the regenerative air preheater alternately First, heated by the hot flue gas and subsequently cooled by the fresh air or a part of the carrying air, an air quantity control means for controlling the combustion air introduced into the combustion chamber, an air quantity control means for controlling the amount of air to be used for the pneumatic conveying of the ground coal and measuring means for measuring the combustion air quantity introduced into the combustion chamber and the amount of carrying air to be used for the pneumatic conveyance of the ground coal and a device for the metered supply of a preselected amount of ground coal to the burners are characterized in that the combustion air quantity measurement is effected by means of a correlation measuring device evaluating triboelectric effects. For this purpose, in the combustion air-carrying channel system in the flow direction of the combustion air after the regenerative air preheater at least two successively positioned sensors for sensing triboelectric effects are arranged, which are in communication with the correlation measuring device, and in the flow direction of the combustion air upstream of the sensors of the correlation measuring device is at least a device for the metered entry of fine-grained particles arranged in the air flow. The device for the metered entry of fine-grained particles into the air stream can preferably be arranged in front of the fresh-air ventilator. However, it is also possible to arrange the device for the metered introduction of fine-grained particles into the air flow between the fresh ventilator and the regenerative air preheater or also after the regenerative air preheater, but in any case before the sensors of the correlation measuring device. The device for metered entry of fine-grained particles into the air stream is dimensioned such that an entry of 0.1 mg to 10 mg, preferably between 0.5 mg to 2 mg, of fine-grained particles per m ^{3 of} air into the air stream. In this case, a control device for controlling the device for the metered entry of fine-grained particles may be provided in the air stream, which allows a continuous and / or a discontinuous, periodic operation of the device for the metered entry of fine-grained particles in the air flow. The carrying air quantity measurement preferably also takes place by means of a correlation measuring device evaluating triboelectric effects. For this purpose, at least two sensors positioned one after the other are arranged in the direction of flow of the carrying air after the regenerative air preheater for the sensing of triboelectric effects, which are connected to the correlation measuring device

The device for the metered entry of fine-grained particles in the air stream is vorzung formed as Staubinjektor, as preferred fine particle particulate filter or fly ash is added to the air stream. The method according to the invention is characterized in that the combustion air quantity measurement and preferably also the carrying air quantity measurement on the basis of the evaluation of triboelectric effects on sensors arranged in the flow direction of the air behind one another in the air flow according to the correlation measuring method and that in the air flow in front of the sensors between 0 , 1 mg to 10 mg, preferably between 0.5 mg to 2 mg, fine particles per m ^{3 of} air with a particle diameter between 20 .mu.m to 200 .mu.m, preferably between 60 .mu.m to 90 .mu.m, registered. It has been found that the entry of 0.1 mg to 10 mg, preferably between 0.5 mg to 2 mg, of fine-grained particles with the aforementioned particle diameters per m ^{3 of} air is sufficient for one measurement. In this case, filter or fly ash is preferably added.

The entry of the fine-grained particles in the air stream preferably takes place only during the start-up phase of the coal-fired power plant firing system, ie during the pre-venting and oil or gas firing phase. After ignition of the pulverized coal combustion, a quantity of ash particles sufficient to effect sufficient triboelectric effects on the sensors is introduced into the fresh air or carrier air stream via the regenerative air preheater, so that the air quantity measurement can be carried out without additional particle introduction according to the correlation measurement method. It has even been shown that a periodic entry of fine-grained particles with a period of 100 ms to 60 s with an entry of 0.1 mg to 10 mg of fine-grained particles per m ^{3 of} air during the start-up phase is sufficient for reliable measurement. The device according to the invention and the method according to the invention make it possible to largely control the fuel-air ratio during the combustion of ground coal in a coal-fired power station without largely experiencing the drift of the air flow measurement known from the prior art. Due to the high long-term stability of the accuracy of the air quantity measurement, the invention enables significantly improved control of the fuel-air ratio.

The invention will be explained in more detail with reference to an embodiment.

The accompanying drawings show in

Figure 1: a simplified block diagram of a coal fired power plant and in Figure 2: the time course of an air flow measurement in a power plant furnace.

The simplified block diagram of a coal-fired power plant shown in FIG. 1 shows, starting with the intake of the fresh air, a fresh air flap 1, a device 2 for the metered introduction of fine-grained particles into the fresh air stream and a fresh ventilator 3. After the fresh ventilator 3, the air drawn from the fresh air is diverted , This is further promoted by a mill fan 4 and although a part of a regenerative air preheater 5. In the regenerative air preheater 5, a portion of the supporting air is heated during steady operation of the coal-fired power plant. Another part of the carrying air is continued cold. Both parts of the carrying air are metered together via the hot air flap 6 and the cold air flap 7, to such proportions that the temperature of the air-coal mixture is after the loading of finely ground coal within preselected limits. The temperature of the carrying air is detected by the arranged behind the coal mill 8 temperature measuring device 9. In front of the coal mill, the sensors of the compressed air quantity measuring device 10 are arranged. These sensors are designed as measuring rods which are arranged one behind the other in pairs in the flow direction of the carrying air and project into the carrying air flow. The carrier air volume measuring device 10 is designed as a correlation measuring device which evaluates the triboelectric effects caused on the measuring rods by the particles carried in the carrying air and thus measures the flow velocity of the carrying air. Based on the cross-sectional area of the air carrying the carrying air in the region of the arranged measuring rods and the temperature of the carrying air and the static pressure of the carrying air in the region of the arranged measuring rods, the carrying air quantity is determined.

The coal mill 8 is charged in accordance with the demanded by the power plant combustion load via a metering device 11 coal. The carrying air laden with ground coal is fed to the burners 13 arranged in a combustion chamber 12. Depending on the design of the coal-fired power plant, this can be done in a single-burner-related or burner-group-wise manner or jointly with all burners 13 of a firing chamber 12. In the flow direction of the carrying air after the regenerative air preheater 5, a pressure measuring device 14 is arranged for detecting the static pressure of the carrying air. In addition, safety flaps 15 are arranged in the carrying air flow, which are closed during the start-up phase of the coal-fired power plant, ie when no ground coal is conveyed to the burners 13. The main part of the fresh air drawn in after the fresh ventilator 3 is burned supply air supplied to the regenerative air preheater 5. The static pressure of the heated combustion air is detected by means of a static pressure measuring device 16. By means of the pressure measuring devices 14 and 16, the control of the fresh ventilator 3 takes place. The heated combustion air is passed to a part directly to the burners 13 and led to another part in the firing chamber 12. Both quantitative components of the combustion air are detected by the combustion air quantity measuring devices 17 and 18.

The combustion air quantity measuring devices 17 and 18, like the carrying air quantity measuring device 10, are designed as correlation measuring devices. The measuring devices have sensors designed as measuring rods, which are arranged in pairs in the direction of flow of the combustion air one behind the other in the combustion air-carrying pipe or channel system. The fine-grained particles guided in the combustion air cause triboelectric effects on the measuring rods, which are evaluated by means of correlation analysis. As a result of the evaluation, the flow rate of the combustion air is determined and the combustion air quantity is determined by taking into account the cross-sectional area of the pipe or duct system guiding the combustion air and the temperature of the combustion air and the static pressure of the combustion air in the region of the arranged measuring rods. The control of the amount of combustion air supplied to the burners 13 and the firing space 12 to achieve a required for a given stoichiometry of combustion fuel-air ratio in accordance with the demand of the power plant firing system load predetermined amount of the burners 13 supplied ground coal by means of the Verbrennungsluft- control flaps 19 and 20.

Depending on the size or capacity of the coal-fired power plant firing system, all of the above-mentioned modules and equipment can be present several times and work in parallel. For the sake of clarity of the simplified block diagram, the modules and devices are only shown in a simple manner. The basic mode of operation of the coal-fired power plant is, as far as the invention is concerned, not affected.

Figure 2 shows the time course of a burner 13 or a group of burners 13 supplied amount of combustion air during the start-up phase of a coal-fired power plant.

The combustion air control flaps 19 and 20 are fully opened while the safety flaps 15 in the carrying air guide are closed. It will only burn tion air into the firing chamber 12 passed. The control of the fresh ventilator 3 takes place as a function of the measured by means of the static pressure measuring device 16 pressure of the combustion air. First, so much combustion air is blown into the firing chamber 12, that a multiple exchange (at least 3 times) of the amount of air in the firing 12 takes place in order to remove fuel residues from the firing chamber 12 and to avoid deflagration. After the multiple replacement of the amount of air in the firing chamber 12, ready for ignition is arranged for in the firing chamber 12 arranged in Figure 1, not shown, oil or gas burners. With the start of the ignition readiness, the amount of combustion air is controlled as a function of the amount of fuel supplied for the ignition process (oil or gas). About the means 2 for the metered entry of fine-grained particles in the fresh air flow 2 m ^{3 of} fly ash are added to the fresh ^¬ air flow per m ³ sucked fresh air. By means of the combustion air quantity measuring devices 17 and 18, the amount of combustion air is measured and controlled via the Verbrennungsluft- control valves 19 and 20, the burners 13 and the combustion chamber 12 supplied amount of combustion air. The oil or gas firing the coal kraftwerksfeuerungsanlage is continued until a sufficient Vorwär ^¬ mung of the combustion chamber 12 and the regenerative air preheater 5 is reached. During the time of oil or gas firing about 2 mg of fly ash per m ^{3 of} fresh air is introduced into the fresh air sucked in order to effect a sufficient particle loading to effect triboelectric effects on the arranged in the combustion air flow sensors and thus to allow the air flow measurement according to the correlation measurement method , Upon reaching a sufficient preheating of the firing chamber 12, the entry of ground coal into the firing chamber 12 begins. For this purpose, the carrier air flow is started via the mill fan 4 and opening the safety flaps 15 and the coal mill 8 dosed fed with coal. The carrying air is loaded with ground coal. The milled coal ignites on the oil or gas burners still in operation.

With the beginning of the coal entry into the firing chamber 12 and the ignition of the coal combustion, the entry of fine-grained particles into the intake fresh air is stopped. A quantity of ash particles sufficient to effect triboelectric effects on the sensor rods of the air quantity measuring devices 10, 17 and 18 is now introduced via the regenerative air preheater 5 into the combustion air and the carrying air. List of reference numbers

1 - Fresh air flap

2 - Device for metered entry of fine-grained particles 3 - Fresh-ventilator

4 - Mill fan

5 - Regenerative air preheater

6 - Hot air flap

7 - cold air flap 8 - coal grinder

9 - Temperature measuring device

10 - carrying air flow meter

11 - Metering device for coal

12 - firing chamber 13 - burner

14 - Pressure measuring device for measuring the static pressure of the carrying air

15 - Safety flap

16 - Pressure measuring device for measuring the static pressure of the

Combustion air 17 - combustion air quantity measuring device

18 - combustion air quantity measuring device

19 - combustion air control flap

20 - combustion air control flap

Claims

claims

1. A device for controlling the fuel-air ratio in the combustion of milled coal in a coal-fired power plant, the means for pneumatically conveying the ground coal to the burners of the coal-fired power plant and means for supplying the combustion air to the burners (13) the firing chamber (12) of the coal-fired power station has at least the following facilities in the flow direction of the air, a fresh ventilator (3) for sucking in fresh air from the environment, a mill ventilator (4) for conveying a part of the fresh air drawn in as carrying air for loading Ground coal, a regenerative air preheater (5) for preheating the fresh air sucked in and part of the carrying air using the flue gas heat of the coal-fired plant firing system, wherein a Speicherermas- se the regenerative air preheater (5) alternately first from the hot

Flue gas is heated and subsequently cooled by the fresh air or a part of the carrying air, an air quantity control device for controlling the amount of combustion air introduced into the firing chamber (12), an air flow control device for controlling the amount of air to be used for the pneumatic conveying of the milled coal and measuring devices ( 10, 17, 18) for measuring the amount of combustion air introduced into the firing space (12) and the amount of carrying air to be used for pneumatically conveying the pulverized coal, and means (8, 11) for metering a preselected amount of ground coal to the burners (13 ), characterized in that for the combustion air quantity measurement (17, 18) a triboelectric effects on two in the combustion air flow, in the flow direction of the combustion air successively arranged sensors evaluating correlation measuring device is provided, wherein the sensors in which the combustion air f In the flow direction of the combustion air in front of the sensors of the correlation measuring device, at least one device (2) for the metered introduction of fine-grained particles into the air flow is arranged in the flow direction of the combustion air.

2. Device according to claim 1, characterized in that for the delivery air quantity measurement (10) a triboelectric effects on two in the carrying air flow, in the flow direction of the carrier air successively arranged sensors evaluating correlation measuring device is provided, wherein the sensors in the carrying air leading channel system in the flow direction of Carrying air after the regenerative air preheater (5) are arranged.

3. Device according to claim 1 or 2, characterized in that the device (2) for the metered entry of fine-grained particles in the air flow in front of the fresh ventilator (3) is arranged.

4. Device according to claim 1, 2 or 3, characterized in that the device (2) for the metered entry of fine-grained particles in the air stream is a Staubinjektor.

5. A device according to claim 4, characterized in that the Staubinjektor is designed for the entry of filter or fly ash in the air flow.

6. Device according to one of the preceding claims, characterized in that the sensors for sensing triboelectric effects in the region of a channel constriction or a channel bend of an air channel are arranged.

7. Device according to one of the preceding claims, characterized in that the sensors for sensing triboelectric effects in the combustion air flow before the adjusting device (19, 29) for controlling the amount of combustion air and in the carrier air flow before the entry of the ground coal in the carrying air ^{flow are} arranged ^¬ .

8. A method for controlling the fuel-air ratio in the combustion of milled coal in a coal power plant, the means for supplying the ground coal to the burners (13) of the coal plant firing system and means for supplying the combustion air to the burners (12) and in the firing chamber (12) of the coal-fired power plant according to claims 1 to 7, characterized in that the combustion air quantity measurement and the Entluftluftmengenmessung on the basis of the evaluation of triboelectric effects on arranged in the flow direction of the air behind the other in the air flow sensors according to the correlation measurement is carried out and in the air flow between 0.1 mg to 10 mg, preferably between 0.5 mg to 2 mg, of fine particles per m ^{3 of} air with a particle diameter between 20 μm to 200 μm, preferably between 60 μm to 90 μm, are entered in front of the sensors.

9. The method according to claim 8, characterized in that the carrying air quantity measurement takes place on the basis of the evaluation of triboelectric effects on in the flow direction of the air in a row in the air flow arrange th sensors according to the correlation measurement method.

10. The method according to claim 8 or 9, characterized in that in the air stream between 0.1 mg to 10 mg, preferably between 0.5 mg to 2 mg, filter or fly ash per m ^{3 of} air is entered.

11. The method according to any one of claims 8 to 10, characterized in that the entry of fine-grained particles in the air flow takes place only during the start-up phase of the coal-fired power plant.

12. The method according to claim 11, characterized in that the entry of fine-grained particles takes place in the air flow when no entry of ground coal takes place in the carrying air.

13. The method according to any one of claims 8 to 12, characterized in that the entry of fine-grained particles in the air flow takes place periodically with a period between 100 ms to 60 s.