Methods of detecting one failure in a burner of a combustor and turbine systems

The invention claimed is: 1. A method of detecting a burner failure, and locating a faulty burner associated with the burner failure, in a combustor of a turbine system, wherein the combustor comprises a plurality of burners arranged annularly, wherein the turbine system comprises a turbine downstream of the combustor, the method comprising the steps of: A) providing a plurality of temperature sensors arranged annularly at an outlet of the turbine; B) detecting a plurality of temperatures through the plurality of temperature sensors; C) calculating a temperature spread indicator as a function of the plurality of temperatures; and D) carrying out a comparison between the temperature spread indicator and a threshold, wherein the temperature spread indicator being greater than the threshold or the temperature spread indicator being greater than the threshold for a set of consecutive cycles of the steps B, C, and D cyclically repeated in time-indicates the burner failure; wherein the method further comprises the steps of: E) identifying an identified temperature sensor of the plurality of temperature sensors that is detecting a minimum temperature; F) determining a sensor angular position of the identified temperature sensor; and G) subtracting an angular shift or an angular shift range from the sensor angular position to obtain a burner position or a burner position range of the faulty burner; wherein a number of sensors of the plurality of sensors is less than a number of burners of the plurality of burners. 2. The method of claim 1 , wherein the steps B, C and D are cyclically repeated in time, and wherein the burner failure is indicated by the temperature spread indicator being greater than the threshold for the set of consecutive cycles. 3. The method of claim 1 , wherein step C comprises the sub-steps of: C1) determining a minimum temperature in the plurality of temperatures, C2) determining a maximum temperature in the plurality of temperatures, and C3) calculating the temperature spread indicator as a difference between the maximum temperature and the minimum temperature. 4. The method of claim 3 , wherein steps B, C and D are cyclically repeated in time; wherein the threshold is a first threshold; wherein an alarm is signaled when consecutively-determined temperature spread indicators in step C are greater than the first threshold over a set of N1 consecutive comparisons in step D; wherein the turbine system is tripped when consecutively-determined temperature spread indicators in step C are greater than a second threshold over a set of N2 consecutive comparisons in step D. 5. The method of claim 1 , comprising the step of signaling an alarm in response to detecting the burner failure. 6. The method of claim 1 , comprising the step of tripping the turbine system in response to detecting the burner failure. 7. The method of claim 1 , wherein the angular shift or the angular shift range depends on an operating status of the turbine system. 8. The method of claim 1 , wherein the step C comprises the sub-steps of: C1) determining a mean temperature being an average of the plurality of temperatures, wherein the temperature spread indicator includes a plurality of values; and C2) calculating the plurality of values of the temperature spread indicator, wherein each value of the plurality of values corresponds to a difference between a respective temperature of the plurality of temperatures and the mean temperature; wherein at the step D, each of the values of the plurality of values is compared with the threshold, and any value of the plurality of values being greater than the threshold or any value of the plurality of values being greater than the threshold for the set of consecutive cycles indicates the burner failure. 9. The method of claim 8 , comprising the step of signaling an alarm in response to detecting the burner failure. 10. The method of claim 8 , comprising the step of tripping the turbine system in response to detecting the burner failure. 11. The method of claim 8 , wherein the steps B, C and D are cyclically repeated in time, and any value of the plurality of values being greater than the threshold for the set of consecutive cycles indicates the burner failure; wherein the threshold is a first threshold; wherein an alarm is signaled when any value of the plurality of values of the temperature spread indicator is greater than the first threshold for a first set of consecutive cycles of the steps B, C, and D cyclically repeated in time; wherein the turbine system is tripped when any value of the plurality of values of the temperature spread indicator is greater than a second threshold for a second set of consecutive cycles of the steps B, C, and D cyclically repeated in time. 12. A turbine system comprising a compressor, a combustor downstream of the compressor, a turbine downstream of the combustor, a plurality of temperature sensors arranged annularly at an outlet of the turbine, and a digital signal processing unit, wherein the combustor comprises a plurality of burners arranged annularly, and the digital signal processing unit is configured to: A) detect a plurality of temperatures through the plurality of temperature sensors; B) calculate a temperature spread indicator as a function of the plurality of temperatures; and C) carry out a comparison between the temperature spread indicator and a threshold, wherein the temperature spread indicator being greater than the threshold or the temperature spread indicator being greater than the threshold for a set of consecutive cycles of A, B, and C cyclically repeated in time indicates a burner failure; wherein the digital signal processing unit, to locate a faulty burner associated with the burner failure, is configured to: D) identify an identified temperature sensor of the plurality of temperature sensors that detects a minimum temperature; E) determine a sensor angular position of the identified temperature sensor; and F) subtract an angular shift or an angular shift range from the sensor angular position to obtain a burner position or a burner position range of the faulty burner; wherein a number of sensors of the plurality of sensors is less than a number of burners of the plurality of burners. 13. The turbine system of claim 12 , wherein the digital signal processing unit is configured to cyclically repeat A, B, and C in time, and the temperature spread indicator being greater than the threshold for the set of consecutive cycles indicates the burner failure. 14. The turbine system of claim 12 , wherein the digital signal processing unit is configured to signal an alarm in response to the burner failure. 15. The turbine system of claim 12 , wherein the digital signal processing unit is configured to trip the turbine system in response to the burner failure. 16. The turbine system of claim 12 , wherein the angular shift or the angular shift range depends on an operating status of the turbine system. 17. The turbine system of claim 12 , wherein the digital signal processing unit is configured to calculate the temperature spread indicator by: B1) determining a mean temperature being an average of the plurality of temperatures, wherein the temperature spread indicator includes a plurality of values; and B2) calculating the plurality of values of the temperature spread indicator, wherein each value of the plurality of values corresponds to a difference between a respective temperature of the plurality of temperatures and the mean temperature; wherein the digital signal processing unit is