ITMI20111941A1 - GAS TURBINE PLANT FOR THE PRODUCTION OF ELECTRICITY AND METHOD TO OPERATE THE PLANT - Google Patents

Description

â € œGAS TURBINE SYSTEM FOR THE PRODUCTION OF ELECTRICITY AND METHOD FOR OPERATING THIS SYSTEMâ €

The present invention relates to a gas turbine plant for the production of electricity and to a method for operating said plant.

During the night, the demand for electricity from the grid drops significantly and the sale price of energy is drastically reduced.

During the night, therefore, the managers of the plants for the production of electricity zero or reduce the power produced to a minimum.

In particular, gas turbine plants of the combined cycle type are not shut down overnight due to too long restart times. In these plants, during the night hours, the power produced is therefore reduced to a minimum.

The minimum power that can be reached by gas turbine systems of the combined cycle type is generally equal to 10% of the rated power. However, at powers of this entity there is an excessive increase in emissions of pollutants (NOx and CO), exceeding the legal limits.

To keep emissions of pollutants at acceptable levels, the minimum power must be greater than 40% of the rated power.

The plant operators also reserve an additional power margin to take into account any fluctuations in polluting emissions due, for example, to a change in environmental conditions, in the composition of the fuel, etc.

It is an aim of the present invention to provide a gas turbine plant for the production of electricity that is capable of generating a minimum power reduced with respect to the minimum powers obtainable up to now and in full compliance with the legal limits relating to emissions of substances. pollutants.

In accordance with these purposes, the present invention relates to a gas turbine plant for the production of electrical energy comprising:

- a gas turbine;

- a combustion chamber fed with fuel;

- a detection module configured to detect at least one first parameter indicative of the concentration of carbon monoxide at the gas turbine exhaust;

- a control device configured to regulate the supply of fuel to the combustion chamber on the basis of a reference power value;

the system being characterized by the fact that the control device comprises calculation means configured to calculate a correction value of the reference power value at least on the basis of the first parameter indicative of the concentration of carbon monoxide and to modify the power value of reference based on the calculated correction value.

It is a further aim of the present invention to provide a method for operating a gas turbine plant which is capable of generating the plant a minimum power reduced with respect to the minimum power obtainable up to now and in full compliance with the relative legal limits. to emissions of pollutants.

In accordance with these purposes, the present invention relates to a method for operating a gas turbine plant for the production of electrical energy; the plant comprising a gas turbine, a combustion chamber fed with fuel and a detection module configured to detect at least a first parameter indicative of the concentration of carbon monoxide at the gas turbine exhaust; the method including the steps of:

â € “adjust the quantity of fuel to be fed to the combustion chamber based on a reference power value;

- calculate a correction value at least on the basis of the first parameter indicative of the concentration of carbon monoxide;

- modify the reference power value based on the calculated correction value.

Further characteristics and advantages of the present invention will become clear from the following description of a non-limiting example of implementation thereof, with reference to the figures of the annexed drawings, in which:

- figure 1 is a schematic representation of a gas turbine electricity production plant according to the present invention;

- figure 2 is a schematic block representation of a first detail of the plant in figure 1.

Figure 1 illustrates a gas turbine plant 1 for the production of electrical energy.

The plant 1 can be selectively connected to an electricity distribution network 2 through a main switch 3 and comprises a gas turbine group 5, a generator 6, a detection module 7, a control device 8 and a control module. selection of reference values 9.

The gas turbine assembly 5 comprises a compressor 10, a combustion chamber 11 and a gas turbine 12. The combustion chamber 11 receives the fuel through a supply valve 13.

The generator 6 is mechanically connected to the same axis as the turbine 12 and the compressor 10 and is driven into rotation at the same angular speed of rotation as the turbine 12 and the compressor 10. The generator 6 transforms the mechanical power supplied by the turbine 12 into power active electrical power, here and hereinafter simply called the delivered power P and makes it available for the distribution network 2 at a given frequency.

A not illustrated variant of the present invention provides that the gas turbo group 5 is coupled to a steam turbo group, which is configured to exploit the heat of the exhaust fumes of the gas turbine 12 to generate steam capable of generating rotation of one or more steam turbines.

The detection module 7 is in communication with a plurality of sensors (not shown) of the system 1 and provides the control device 8 with a series of parameters relating to the system 1, such as parameters indicative of the concentration of carbon monoxide CO% at the turbine exhaust 12, parameters indicative of the concentration of nitrogen oxides NOx% at the turbine exhaust 12, frequency of the system fI, power P delivered, temperature of the gases at the turbine exhaust 12, etc.

The reference value selection module 9 generates reference signals to be fed to the control device 8. In particular, the reference value selection module 9 supplies to the control device 8 at least one predefined power value SPDEF.

The control device 8 uses the parameters coming from the detection module 7 and from the reference value selection module 9 to generate control signals suitable for regulating the fuel supply to the combustion chamber 11 and the flow of air fed to the compressor 10.

In particular, the control device 8 generates a UFV control signal which is sent to the valve 13 to regulate the supply of fuel to the combustion chamber 11.

The control device 8 comprises a plurality of control modules (not shown in the figure) by means of which the system variables are controlled, such as the frequency of the system, the power P delivered, the temperature of the gases at the turbine exhaust 12, etc.

In particular, the control device 8 comprises a power regulation module 15, an adder node 16 and a set point regulation module 17.

The power regulation module 15 controls the power P delivered by the system 1 on the basis of a reference power value SP, commonly called â € œload set pointâ €. In particular, the power regulation module 15 receives at its input an actual power value P delivered, coming from the detection module 7, and a reference power value SP supplied by the summing node 16. The summing node 16 calculates the power value of SP reference as the sum of the predefined power value SPDEF coming from the reference value selection module 9 and a power correction value SPC coming from the set point regulation module 17.

On the basis of the input data, the power regulation module 15 generates a control signal UÎ "P to control the fuel supply valve 13 to the combustion chamber 11. Preferably, the power control module 15 is made according to a control logic PID (Proportional Integral Derivative) based on a power error, i.e. the difference between the current power P and the reference power value SP.

The set point regulation module 17 receives from the detection module 7 at least one parameter indicative of the concentration of carbon monoxide CO% at the exhaust of the turbine 12 and at least one parameter indicative of the concentration of nitrogen oxides NOx% at the exhaust of the turbine 12.

In the non-limiting example described and illustrated here, the indicative parameter of the concentration of carbon monoxide CO% is the concentration (expressed in percentage terms) of carbon monoxide CO% detected at the exhaust of the gas turbine 12, while the indicative parameter of the concentration of nitrogen oxides NOx% is the concentration (expressed in percentage terms) of nitrogen oxides NOx% measured at the gas turbine exhaust 12.

Preferably, the concentration of carbon monoxide CO% and the concentration of nitrogen oxides NOx% is detected by means of respective dedicated sensors.

The set point regulation module 17 therefore generates a correction value SPC of the reference power value SP based on the parameter indicative of the concentration of carbon monoxide CO% and on the basis of the parameter indicative of the concentration of nitrogen oxides. NOx%.

With reference to Figure 2, the set point regulation module 17 comprises a first calculation module 20, configured to calculate a first corrective term SPCO on the basis of the indicative parameter of the concentration of carbon monoxide CO%, a second calculation module 21, configured to calculate a second corrective term SPNOx on the basis of the second indicative parameter of the concentration of nitrogen oxides NOx%, and an adder node 22 configured to add the first corrective term SPCO to the second corrective term SPNOx and generate the SPC correction value of the reference power value SP.

In particular, the first calculation module 20 comprises a calculation block 24, configured to calculate the corrective term SPCO% on the basis of the difference between the parameter indicative of the concentration of carbon monoxide CO% detected and a predefined REFCO reference value.

The corrective term SPCO% leaving the calculation block 24 is expressed in the unit of measurement used for the concentration of carbon monoxide detected (in percentage terms in the non-limiting example described and illustrated here).

The corrective term SPCO% in output from the calculation block 24 is then converted into MW by a predefined conversion factor KCO. The adder node 22 will then be fed the corrective term SPCOMW expressed in MW.

Preferably, calculation block 24 is made according to a PID (Proportional Integral Derivative) control logic based on the error between the detected parameter indicative of the concentration of carbon monoxide CO% and the REFCO reference value.

The second calculation module 21 comprises a calculation block 26, configured to calculate the second corrective term SPNOx% on the basis of the difference between the parameter indicative of the concentration of nitrogen oxides NOx% detected and a predefined REFNOx reference value.

The corrective term SPNOx% leaving the calculation block 26 is expressed in the unit of measurement used for the concentration of nitrogen oxides detected (in percentage terms in the non-limiting example described and illustrated here).

The corrective term SPNOx% at the output of the calculation block 26 is then converted into MW by a predefined conversion factor KNOx. The adder node 22 will then be fed the corrective term SPNOxMW expressed in MW.

Preferably, the calculation block 26 is made according to a PID (Proportional Integral Derivative) control logic based on the error between the detected parameter indicative of the concentration of nitrogen oxides NOx% and a REFNOx reference value.

Basically, the SPC correction value exiting the adder node 22 is the sum of the first corrective term SPCOMW and the second corrective term SPNOxMW.

Preferably, the control device 8 comprises an activation device 28, configured to selectively activate the correction of the reference power value SP. In detail, the activation device 28 is substantially a selector having two operating positions: an active position in which the activation device 28 connects the set point correction module 17 to the adder node 16 to feed the correction value to the adder node 16 SPC and a second operating position in which the activation device 28 supplies a signal equal to zero to the adder node 16 to prevent correction of the reference power value SP. The activation device 28 is preferably controlled by means of a two-state pushbutton 30 which can be activated by an operator.

Advantageously, the control device 8 of the plant 1 according to the present invention is configured in such a way as to correct the reference power value SP on the basis of the level of emissions of pollutants (CO and NOx). This type of regulation allows plant operators to set a minimum SPDEF predefined power value lower than the minimum predefined power values currently used.

Thanks to the present invention, the safety margin considered up to now for defining the minimum SPDEF predefined power value for night-time operation can be reduced or even zeroed without running the risk of exceeding the legal limits relating to pollutant emissions. .

The control device 8, in fact, is able to raise the reference power value SP when the emissions come dangerously close to the legal limits, for example due to changes in external environmental conditions.

In this way, the minimum power produced by the plant 1 is advantageously reduced during the night, with a considerable saving for the plant operators. The cost of selling energy per MW / h during the night is, in fact, lower than the cost of production.

The present invention is also advantageous because it allows to reduce to a minimum the power produced by thermal power plants to the advantage of renewable sources and nuclear power.

Finally, it is evident that modifications and variations may be made to the gas turbine plant for the production of electricity and to the method for operating said plant described here without departing from the scope of the attached claims.

Claims (17)

CLAIMS 1. Gas turbine plant for the production of electricity comprising: - a gas turbine (12); - a combustion chamber (11) fed with fuel; - a detection module (7) configured to detect at least one first parameter indicative of the concentration of carbon monoxide (CO%) at the gas turbine exhaust (12); - a control device (8) configured to regulate the supply of fuel to the combustion chamber (11) on the basis of a reference power value (SP); the system being characterized by the fact that the control device (8) comprises calculation means (16, 17) configured to calculate a correction value (SPC) of the reference power value (SP) at least on the basis of the first parameter indicative of the carbon monoxide concentration (CO%) and modify the reference power value (SP) according to the calculated correction value (SPC). 2. Plant according to claim 1, wherein the detection module (7) is configured to detect at the discharge of the gas turbine (12) at least a second parameter indicative of the concentration of nitrogen oxides (NOx%); the calculation means (16, 17) being configured to calculate the correction value (SPC) also on the basis of the second parameter indicative of the concentration of nitrogen oxides (NOx%). Plant according to claim 1 or 2, wherein the calculation means (17) comprise a first calculation module (24) configured to calculate a first corrective term (SPCO) based on the parameter indicative of the carbon monoxide concentration ( CO%). 4. Plant according to claim 3, wherein the calculation means (17) comprise a second calculation module (26) configured to calculate a second corrective term (SPNOx) on the basis of the second parameter indicative of the concentration of nitrogen oxides (NOx %). 5. Plant according to claim 4, wherein the calculation means (17) comprises an adder node (22) configured to calculate the correction value (SPC) as the sum of the first corrective term (SPCO) and the second corrective term (SPNOx ). Plant according to any one of claims 3 to 5, wherein the first calculation module (24) is configured to calculate the first corrective term (SPCO) on the basis of the difference between the indicative parameter of the carbon monoxide concentration ( CO%) and a first reference value (REFCO). 7. Plant according to claim 6, wherein the first computing module (24) comprises a controller of the PID type. 8. Plant according to any one of claims 4 to 7, wherein the second calculation module (26) is configured to calculate the second corrective term (SPNOx) on the basis of the difference between the second indicative parameter of the nitrogen oxide concentration (NOx%) and a second reference value (REFNOx). System according to claim 6, wherein the second computing module (26) comprises a controller of the PID type. 10. Method for operating a gas turbine plant 1 for the production of electrical energy; the plant (1) comprising a gas turbine (12), a combustion chamber (11) fed with fuel and a detection module (7) configured to detect at least one first parameter at the gas turbine exhaust (12) indicative of the concentration of carbon monoxide (CO%); the method including the steps of: - adjust the quantity of fuel to be fed to the combustion chamber (11) on the basis of a reference power value (SP); - calculate a correction value (SPC) at least on the basis of the first parameter indicative of the concentration of carbon monoxide (CO%); - modify the reference power value (SP) based on the calculated correction value (SPC). Method according to claim 10, wherein the step of changing the reference power value (SP) comprises the step of adding the calculated correction value (SPC) to a predefined power value (SPDEF). Method according to claim 10 or 11, wherein the step of calculating a correction value (SPC) comprises the step of calculating a first corrective term (SPCO) based on the parameter indicative of the carbon monoxide concentration (CO%) . Method according to claim 12, wherein the detection module (7) is configured to detect at the exhaust of the gas turbine (12) at least a second parameter indicative of the concentration of nitrogen oxides (NOx%); the step of calculating a correction value (SPC) including the step of calculating the correction value (SPC) also based on the second parameter indicative of the concentration of nitrogen oxides (NOx%). Method according to claim 13, wherein the step of calculating a correction value (SPC) comprises the step of calculating a second corrective term (SPNOx) on the basis of the second parameter indicative of the concentration of nitrogen oxides (NOx%). Method according to claim 14, the step of calculating a correction value (SPC) comprises the step of calculating the correction value (SPC) as the sum of the first corrective term (SPCO) and the second corrective term (SPNOx). Method according to any one of claims 12 to 15, wherein the step of calculating a first corrective term (SPCO) comprises calculating the first corrective term (SPCO) based on the difference between the indicative parameter of the carbon monoxide concentration ( CO%) and a first reference value (REFCO). Method according to any one of claims 14 to 16, wherein the step of calculating a second corrective term (SPNOx) comprises the step of calculating the second corrective term (SPNOx) on the basis of the difference between the second parameter indicative of the concentration of nitrogen oxides (NOx%) and a second reference value (REFNOx).