Method and system for cooling down a gas turbine

The invention claimed is: 1. A method for cooling down a gas turbine, comprising: running down the gas turbine from a power mode thereof to a cool-down mode, and injecting a liquid into air sucked in by a compressor of the gas turbine during the cool-down mode, wherein the liquid is injected into the sucked-in air in dependence on an air humidity of the sucked-in air, a flow velocity of cooling air flowing in the gas turbine in the region of at least one flow-guiding component, which is to be cooled, of the gas turbine, and a temperature difference between a temperature of the cooling air flowing in a region of the at least one flow-guiding component to be cooled and a temperature of the at least one flow-guiding component of the gas turbine. 2. The method as claimed in claim 1 , wherein an opening cross section of an inlet into the compressor is at least partially enlarged during the cool-down mode by means of appropriate control of adjustable inlet guide vanes. 3. A method for cooling down a gas turbine, comprising: running down the gas turbine from the power mode thereof to a cool-down mode, and injecting a liquid into air sucked in by a compressor of the gas turbine during the cool-down mode, wherein the liquid is injected into the sucked-in air in dependence on an air humidity of the sucked-in air, a flow velocity of cooling air flowing in the gas turbine in the region of at least one flow-guiding component, which is to be cooled, of the gas turbine, and a temperature difference between a temperature of the sucked-in air and a temperature of the at least one flow-guiding component of the gas turbine. 4. The method as claimed in claim 3 , wherein an opening cross section of an inlet into the compressor is at least partially enlarged during the cool-down mode by means of appropriate control of adjustable inlet guide vanes. 5. A system for cooling down a gas turbine, having comprising at least one device for injecting a liquid into air sucked in by a compressor of the gas turbine, which device is arranged upstream of the compressor, and at least one electronic open-loop and/or closed-loop control unit connected to the device in terms of signal engineering and configured to control the device in an appropriate manner in order to inject the liquid into the sucked-in air during a cool-down mode of the gas turbine, wherein the system comprises: at least one sensor unit for detecting an air humidity of the sucked-in air, at least one sensor unit for detecting a flow velocity of cooling air flowing in the gas turbine in the region of at least one flow-guiding component, which is to be cooled, of the gas turbine, at least one sensor unit for detecting a temperature of the cooling air flowing in a region of the at least one flow-guiding component to be cooled, and at least one sensor unit for detecting a temperature of the at least one flow-guiding component of the gas turbine, wherein the sensor units are connected to the electronic open-loop and/or closed-loop control unit in terms of signal engineering, and wherein the electronic open-loop and/or closed-loop control unit is configured to determine a temperature difference between the temperature of the cooling air flowing in the region of the at least one flow-guiding component to be cooled and the temperature of the at least one flow-guiding component of the gas turbine and to control the device in such a way that the liquid is injected into the sucked-in air in dependence on the respectively detected air humidity of the sucked-in air, the respectively detected flow velocity of the cooling air and the respectively detected temperature difference between the temperature of the cooling air flowing in the region of the at least one flow-guiding component to be cooled and the temperature of the at least one flow-guiding component of the gas turbine. 6. The system as claimed in claim 5 , comprising: at least one assembly connected to the electronic open-loop and/or closed-loop control unit in terms of signal engineering, for varying an opening cross section of an inlet into the compressor, which assembly has at least one inlet guide vane ring comprising adjustable inlet guide vanes, wherein the electronic open-loop and/or closed-loop control unit is configured to control the assembly in a manner appropriate to the at least partial enlargement of the opening cross section of the inlet into the compressor during the cool-down mode. 7. A system for cooling down a gas turbine, having at least one device for injecting a liquid into air sucked in by a compressor of the gas turbine, which device is arranged upstream of the compressor, and at least one electronic open-loop and/or closed-loop control unit connected to the device in terms of signal engineering and configured to control the device in an appropriate manner in order to inject the liquid into the sucked-in air during a cool-down mode of the gas turbine, wherein the system comprises: at least one sensor unit for detecting an air humidity of the sucked-in air, at least one sensor unit for detecting a flow velocity of cooling air flowing in the gas turbine in the region of at least one flow-guiding component, which is to be cooled, of the gas turbine, at least one sensor unit for detecting a temperature of the sucked-in air, and at least one sensor unit for detecting a temperature of the at least one flow-guiding component of the gas turbine, wherein the sensor units are connected to the electronic open-loop and/or closed-loop control unit in terms of signal engineering, and wherein the electronic open-loop and/or closed-loop control unit is configured to determine a temperature difference between the temperature of the sucked-in air and the temperature of the at least one flow-guiding component of the gas turbine and to control the device in such a way that the liquid is injected into the sucked-in air in dependence on the respectively detected air humidity of the sucked-in air, the respectively detected flow velocity of the cooling air and the respectively detected temperature difference between the temperature of the sucked-in air and the temperature of the at least one flow-guiding component of the gas turbine. 8. The system as claimed in claim 7 , comprising at least one assembly connected to the electronic open-loop and/or closed-loop control unit in terms of signal engineering, for varying an opening cross section of an inlet into the compressor, which assembly has at least one inlet guide vane ring comprising adjustable inlet guide vanes, wherein the electronic open-loop and/or closed-loop control unit is configured to control the assembly in a manner appropriate to the at least partial enlargement of the opening cross section of the inlet into the compressor during the cool-down mode.