A gas turbine and method are disclosed by which the gas turbine can be safely operated at nominal speed with reduced margin to a surge limit of a compressor. The gas turbine, via a directly driven generator which generates alternating current with an operating frequency and which is connected in a f
A gas turbine and method are disclosed by which the gas turbine can be safely operated at nominal speed with reduced margin to a surge limit of a compressor. The gas turbine, via a directly driven generator which generates alternating current with an operating frequency and which is connected in a frequency-coupled manner to an electricity grid, can deliver electric power to this grid. In the case of an underfrequency event the compressor of the gas turbine is unloaded by controlled, fast closing of the variable compressor guide vanes (VGV) and as a result maintains a sufficient margin to the surge limit of the compressor.
대표청구항▼
1. A gas turbine for driving a generator to generate alternating current with an operating frequency, and for communication in a frequency-coupled manner with a grid having a given grid frequency, the gas turbine comprising: a compressor having variable compressor guide vanes, wherein the compressor
1. A gas turbine for driving a generator to generate alternating current with an operating frequency, and for communication in a frequency-coupled manner with a grid having a given grid frequency, the gas turbine comprising: a compressor having variable compressor guide vanes, wherein the compressor and turbine are arranged on a single shaft, the shaft configured to be coupled to the generator; anda closed-loop controller connected to the variable compressor guide vanes for closing the variable compressor guide vanes during an underfrequency event of the grid, as a function of a gas turbine speed, with a speed so that a surge limit margin of a compressor is maintained during the underfrequency event of the grid. 2. The gas turbine as claimed in claim 1, wherein a control speed of the variable compressor guide vanes is more than 5°/s. 3. The gas turbine as claimed in claim 1, wherein a control speed of the variable compressor guide vanes is more than 10°/s. 4. The gas turbine as claimed in claim 1, wherein actuators of the variable compressor guide vanes can be operated faster than 10°/s. 5. The gas turbine as claimed in claim 1, wherein the closed-loop controller of the variable compressor guide vanes has actuators, transducers of angular position of the variable compressor guide vanes, and a governor for a closed-loop controlling with more than 10°/s angular speed. 6. The gas turbine as claimed in claim 3, wherein actuators of the variable compressor guide vanes can be operated faster than 10°/s. 7. The gas turbine as claimed in claim 6, wherein the closed-loop controller of the variable compressor guide vanes includes the actuators, transducers of angular position of the variable compressor guide vanes, and a governor for a closed-loop controlling with more than 10°/s angular speed. 8. A method for operating a gas turbine for driving a generator that is in communication in a frequency coupled manner with a grid, the grid having a given frequency, the generator generating alternating current with an operating frequency, the gas turbine having a compressor having variable compressor guide vanes and a closed-loop controller connected to the variable compressor guide vanes, wherein the compressor and turbine are arranged on a single shaft, the shaft configured to be coupled to the generator the method comprising: determining a dynamic limit of a permissible mechanical speed (nmech) in dependence upon ambient conditions; andwhen the mechanical speed falls below this limit, closing the variable compressor guide vanes during an underfrequency event of the grid as a function of a gas turbine speed with a speed so that, a surge limit margin of the compressor is maintained during the underfrequency event of the grid. 9. The method as claimed in claim 8, wherein the dynamic limit of the permissible mechanical speed (nmech) is determined in dependence upon the position of the variable compressor guide vanes. 10. The method as claimed in claim 8, wherein the ambient conditions are determined by an ambient factor (aF) calculated as a quotient of one and a square root of a product of an isentropic exponent (k), gas constant (R) and compressor inlet temperature (T). 11. The method as claimed in claim 8, wherein the ambient conditions are determined by an ambient factor (aF) calculated as a quotient of one and a square root of a product of an isentropic exponent (k), gas constant (R) and compressor inlet temperature (T) wherein (k) and (R) are approximated as a function of relative air humidity of inlet air. 12. The method as claimed in claim 8, wherein the ambient conditions are determined by an ambient factor (aF) calculated as a quotient of one and a square root of a product of an isentropic exponent (k), gas constant (R) and compressor inlet temperature (T) wherein R is approximated as a function of a relative air humidity of inlet air. 13. The method as claimed in claim 8, wherein fuel mass flow is reduced during or after the closing of the variable compressor guide vanes during the underfrequency event of the grid.
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이 특허에 인용된 특허 (13)
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