Method and device for controlling the spraying of water into the flue gas duct of a gas and steam turbine installation

The invention claimed is: 1. A method for operating a gas and steam turbine installation comprising a gas turbine that provides heat via an expanded flue gas in a flue gas duct to a waste heat steam generator (WHSG), in which the heat contained in the expanded flue gas of the gas turbine is used to generate steam in steam carrying tubes of the WHSG that form a part of a water-steam circuit of a steam turbine, the method comprising: reducing a temperature of the expanded flue gas to avoid a critical operating state by: measuring, with a first temperature sensor, a first temperature value of the temperature of the expanded flue gas at a first measuring point ahead of the introduction of the water into the expanded flue gas with regard to flow, measuring, with a second temperature sensor, a second temperature value of the temperature of the expanded flue gas at a second measuring point in the flue gas downstream of the first measuring point, correcting the first temperature value from the first measuring point with the second temperature value from the second measuring point, determining an average combustion temperature of the gas turbine from the corrected first temperature value of the temperature of the expanded flue gas, setting an amount of water to be introduced into the expanded flue gas in the flue gas duct between the gas turbine and the WHSG on the basis of the average combustion temperature, and thermally decoupling the gas turbine from the steam turbine during a load-change process of the gas and steam turbine installation by setting an inlet temperature of the WHSG, and maintaining the WHSG inlet temperature by said introducing of the water into the expanded flue gas, operating the gas turbine within an operating range thereof during the load-change process without restriction by an operating range of the WHSG and the steam turbine, and operating the WHSG and the steam turbine within the operating range thereof during the load-change process without restriction by the operating range of the gas turbine. 2. The method as claimed in claim 1 , wherein the average combustion temperature is set on the basis of a function derived from the corrected first temperature value of the temperature of the expanded flue gas in the flue gas duct, from a steam temperature in a pressure stage of the WHSG, from load transients of the gas turbine and steam turbine and from limits for the steam turbine. 3. The method as claimed in claim 1 , further comprising: further thermally decoupling the gas turbine from the steam turbine by injecting, with water injection devices, further water into the steam-carrying tubes of the water-steam circuit to maintain the operating range of the WHSG and the steam turbine by cooling the steam, and interlinking a control of the injection of the further water into the steam-carrying tubes with a control of the introduction of water into the flue gas duct to effect the further thermal decoupling over a range of operating conditions. 4. A gas and steam turbine installation, comprising: a flue gas duct; a waste heat steam generator (WHSG); a gas turbine that provides heat via an expanded flue gas in the flue gas duct to the WHSG, a nozzle arrangement for the introducing a water into the flue gas duct; a first temperature sensor configured to measure a first temperature value of a temperature of the expanded flue gas at a first measuring point in the flue gas duct ahead of the introducing of the water into the flue gas duct; a second temperature sensor configured to measure a second temperature value of the temperature of the expanded flue gas at a second measuring point in the flue gas duct downstream of the first measuring point; and a control element configured to receive signals from the first temperature sensor and the second temperature sensor indicating the first temperature value and the second temperature value and further configured to correct the first temperature value with the second temperature value; and wherein the control element further determines an average combustion temperature of the gas turbine from the corrected first temperature value and sets an amount of the water to be introduced through the nozzle arrangement on the basis of the average combustion temperature. 5. The gas and steam turbine installation as claimed in claim 4 , wherein the nozzle arrangement is configured to spray the water introduced into the flue gas duct. 6. The method as claimed in claim 1 , wherein the load-change process comprises a start-up process comprising: running-up the gas turbine to a full load before the WHSG and the water-steam circuit have been preheated, and thus cannot yet be operated; and during said running-up, heating the WHSG and the water-steam circuit more gradually than the gas turbine, using the heat of the expanded flue gas. 7. The method as claimed in claim 1 , wherein the first measuring point is at an inlet of the flue gas duct. 8. The method as claimed in claim 1 , wherein the decoupling is performed without using a flue bypass to discharge the expanded flue gas from the flue gas duct before it reaches the WHSG. 9. The method as claimed in claim 1 , wherein the first measuring point and the second measuring point are both ahead of the introduction of the water into the expanded flue gas with regard to flow. 10. The method as claimed in claim 1 , wherein the second measuring point is after the introduction of the water into the expanded flue gas with regard to flow. 11. The method as claimed in claim 1 , wherein a fluctuation in the first temperature value of the expanded flue gas at the first measuring point is greater than a fluctuation in the second temperature value of the expanded flue gas at the second measuring point. 12. The method as claimed in claim 3 , further comprising measuring a temperature of the steam in the steam-carrying tubes. 13. The method as claimed in claim 12 , wherein the measuring comprises: measuring, with a third temperature sensor, a third temperature value of the temperature of the steam in the steam-carrying tubes at a third measuring point ahead of the injection of the further water into the steam-carrying tubes; and measuring, with a fourth temperature sensor, a fourth temperature value of the temperature of the steam in the steam-carrying tubes at a fourth measuring point after the injection of the further water into the steam-carrying tubes; and controlling, with an actuator, the water injection device, based on the third temperature value and the fourth temperature value. 14. The gas and steam turbine installation of claim 4 , wherein the flue gas duct surrounds the steam generator.