Method for operating a gas turbine arrangement

The invention claimed is: 1. A method for operating a gas turbine arrangement connected to a grid system, the method comprising: separating a compressor and a turbine including a combustor to rotate on separate shafts to operate both components individually, wherein a first unit includes the turbine and at least one generator and a second unit includes the compressor and at least one motor, wherein a first switch, a second switch and a third switch are situated along respective first, second and third power lines and are connected to a frequency converter and the grid system; and introducing an air mass flow from the compressor to the combustor of the turbine via a compressed air duct including a flap operating downstream of the compressor. 2. The method according to claim 1 , wherein the first switch is arranged along the first power line arranged between the generator and the grid system or vice versa, the second switch is arranged along the second power line which operates between the first power line and the frequency converter or vice versa, the third switch is arranged along the third power line which operates between the motor and the frequency converter or vice versa, and wherein a fourth power line operates between the frequency converter and the grid system or vice versa. 3. The method according to claim 1 , wherein operating of the gas turbine arrangement refers to at least one or a sequential process or a variable combination of the following modes: a standstill mode; a ready-to-start mode; a start-up and ignition mode; a loading mode; a shut-down mode; and/or a gas turbine trip mode. 4. The method according to claim 3 , the standstill mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; opening the first, second and third switches; and closing the flap. 5. The method according to claim 3 , the ready-to-start mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; running the first unit to a speed via the fourth power line from the grid system to the frequency converter; closing the second switch arranged along the second power line, while the first switch and the third switch remain opened; opening the flap for introducing the air mass flow from the compressor to the combustor to introduce a slight air mass flow; choosing a speed to turn the turbine/generator shaft such that the turbine is heated up via ventilation of blades of the turbine in the area of 1000 rpm. 6. The method according to claim 3 , the start-up and ignition mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; running the first unit to nominal speed corresponding to a grid frequency; closing the first switch arranged along the first power line, such that the generator operates as a motor; opening the second switch; opening the flap; and driving the second unit to a speed n 2 via the third power line by the frequency converter by closing the third switch, wherein speed n 2 corresponds to an ignition speed of the combustor of the gas turbine arrangement. 7. The method according to claim 3 , the loading mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; gradually increasing a fuel flow and a compressed air mass flow in a composition by a controller wherein a) the fuel flow is directed by a fuel control valve; b) the compressed air mass flow is directed by the frequency converter; c) the flap is opened; and driving the second unit by the frequency converter by closing the third switch, wherein the generator is first consuming electrical energy from the grid system and by increasing a thermal power of the combustor, an electrical load consumption is reduced and the generator starts to export energy via a power line by closing the first switch, wherein the generator is always connected to the grid system in such a way that no re-synchronization is needed. 8. The method according to claim 3 , the shut-down mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; reducing a thermal power of the combustor until no combustion process is present in the combustor; closing a control valve; opening the first switch, wherein a turbine/generator shaft is slowing down and when stopped the rotor barring driving the first unit is started, wherein the third switch is opened and a compressor/motor unit shaft is quickly running down and at standstill, the rotor barring driving the second unit is started; closing the flap to keep the turbine warm, wherein in keeping ready to start mode an opened second switch is closed and a speed n 1 is kept. 9. The method according to claim 3 , the gas turbine trip mode comprising: driving the first unit by a rotor barring; driving the second unit by a rotor barring; stopping a fuel flow by immediate closing of a fuel control valve and a trip valve; simultaneously opening the third switch and a compressor/motor unit shaft is slowing down, wherein as soon as the generator consumes energy, opening the first switch and a turbine/generator unit shaft is slowing down, closing the flap to keep the turbine warm and a point of time to close of the flap avoids a compressor surge, closing an opened second switch and keeping a speed n 1 to keep the turbine on ready to start mode. 10. The method according to claim 1 , wherein the turbine and the generator are associated with a steam power station which has a controller which controls the gas turbine and the steam power station, and which controller causes initiation of the generator when there is a power demand on the steam power station which exceeds a specific limit.