Method to start up a combined cycle thermal plant for energy production from an off-state to an operational state

The invention claimed is: 1. A method to minimize time for the start up of a combined cycle thermal plant for energy production from an off-state to an operational state, said combined cycle thermal plant for energy production comprising a first gas turbine and generator group (TGI), a first recovery steam generator (GRV 1 ) to regenerate latent heat of exhaust gases of said first gas turbine and generator group (TGI), a steam turbine (TV), a generator coupled to said steam turbine (TV), and a nozzle/steam distributor, wherein: said first recovery steam generator (GRV 1 ) is in fluid communication with said steam turbine (TV), said first recovery steam generator (GRV 1 ) is kinematicly coupled to said steam turbine (TV) to be rotationally operated and, said combined cycle thermal plant is configured to monitor and detect a plurality of parameters connected to the correct functioning and/or malfunctioning of said first gas turbine and generator group (TGI) and said first recovery steam generator (GRV 1 ) and, respectively of said steam turbine (TV), a first stage of said steam turbine comprises a wheel chamber to be fed with steam produced by said first recovery steam generator (GRV 1 ) through a nozzle/steam distributor, wherein the start-up phases of the combined cycle thermal plant starting from an off-state comprise, in order, the following sequence of functions: GF 1 A: prearranging said first gas turbine and generator group (TGI) for start-up; GF 2 A: starting-up of said first gas turbine and generator group (TGI) and pressurizing of said first recovery steam generator (GRV 1 ); GF 3 A: warming-up and increasing load of said steam turbine (TV) with steam at a set pressure coming from said first recovery steam generator (GRV 1 ); wherein the start-up time of the combined cycle thermal plant starting from an off-state comprises the sum of the following times: time for washing and start-up time of the first gas turbine and generator group (TGI); pressurizing time of the first recovery steam generator (GRV 1 ) and warm-up time of the steam turbine (TV); wherein a steam optimum temperature (θ v1 ) to be introduced in the steam turbine in order to execute the warm-up of said steam turbine (TV) with steam at a set warm-up pressure (P h ) and for a set warm-up time (T r ) is determined as follows: a) establishing for the steam turbine (TV) a correlation between a minimum warm-up time to be implemented for the steam turbine (TV) taking into account any difference in temperature between a temperature of steam introduced inside the wheel chamber of said first stage of the steam turbine (TV) and a metal temperature (θ m1 ) of the wheel chamber of said first stage of the steam turbine (TV), b) determining, on the basis of said set warm-up time (T r ) and of said correlation, a maximum allowable difference in temperature (Δθ 1 ) between the temperature of the steam introduced in the wheel chamber of said first stage of the steam turbine (TV) and the metal temperature (θ m1 ) of the wheel chamber of said first stage of the steam turbine (TV); c) detecting the metal temperature (θ m1 ) of the wheel chamber of said first stage of the steam turbine (TV); d) determining, taking into account the geometrical and structural features of the nozzle/steam distributor, an enthalpy drop (ΔH 1 ) corresponding to the enthalpy decrease steam undergoes when passing through said nozzle/steam distributor; e) determining a calculated enthalpy (H 1 ) of steam to be introduced into the steam turbine (TV) by making the algebraic sum of said enthalpy drop (ΔH 1 ) and an enthalpy of steam having a pressure equal to said warm-up pressure (P h ) and a temperature equal to the algebraic sum of said detected metal temperature (θ m1 ) of the wheel chamber of said first stage and of said maximum allowable difference in temperature (Δθ 1 ); f) determining, on the basis of said calculated enthalpy (H 1 ) and of said set warm-up pressure (P h ), the steam optimum temperature (θ v1 ) to be introduced inside the steam turbine (TV) so as to be able to warm up said steam turbine (TV) within said set warm-up time (T r ) with steam at said set warm-up pressure (P h ). 2. The method of claim 1 , wherein: said steam turbine (TV) is a multi-stage steam turbine comprising high, medium and low pressure stages; said first recovery steam generator (GRV 1 ) is in fluid communication through steam lines at high, medium and low pressure having corresponding stages at high, medium and low pressure of said steam turbine (TV), each one of said stages comprising a corresponding wheel chamber to be fed with steam through a respective nozzle/steam distributor, said first stage is the high pressure stage of said steam turbine (TV) and said warm-up pressure (P h ) is the warm-up pressure of said high pressure stage. 3. The method of claim 2 , wherein said medium pressure stage is warmed up with steam having a pressure (P m ) during said warm-up time (T r ), the method further comprising: determining a second steam optimum temperature (θ v2 ) to be introduced in the medium pressure stage of the steam turbine (TV) by repeating steps a) to f) for the medium pressure stage; and choosing a gas turbine load so as to generate steam having a temperature as close as possible to one of the sets θ v1 and θ v2 . 4. The method of claim 1 , wherein said warm-up time (T r ) is comprised within fifteen minutes and ninety minutes. 5. The method of claim 2 , wherein said combined cycle thermal plant comprises: a second gas turbine and generator group (TG 2 ), a second recovery steam generator (GRV 2 ) to regenerate latent heat of exhaust gases of said second gas turbine and generator group (TG 2 ); said second recovery steam generator (GRV 2 ) being in fluid communication through a high pressure steam collector (CAP), through a medium pressure steam collector (CMP) and through a low pressure steam collector (CBP) with said high, medium and low pressure steam lines of said first recovery steam generator (GRV 1 ) to feed said high, medium and low pressure stages of said steam turbine (TV) through a steam parallelism at high, medium and low pressure between said first recovery steam generator (GRV 1 ) and said second recovery steam generator (GRV 2 ), the method further comprising: GF 4 A: prearranging said second gas turbine and generator group (TG 2 ) for start-up; GF 5 A: starting-up of said second gas turbine and generator group (TG 2 ) and pressurization of said second recovery steam generator (GRV 2 ) and GF 6 A: inserting of a steam parallelism between said second recovery steam generator (GRV 2 ) and said first recovery steam generator (GRV 1 ) through said steam collectors at high (CAP), medium (CMP) and low (CBP) pressure respectively feeding said high, medium and low pressure stages of said steam turbine (TV). 6. The method of claim 1 , wherein said pressurization time of the first recovery steam generator (GRV 1 ) is determined in the following way: defining a pressure increase rate of the first recovery steam generator (GRV 1 ) on the basis of first recovery steam generator (GRV 1 ) features and of a thermal load transferred to said first recovery steam generator (GRV 1 ) by exhaust gases of the first gas turbine and generator group (TGI); detecting an initial temperature inside the first recovery steam generator (GRV 1 ); calculating a difference in temperature between a steam temperature necessary to warm up the steam turbine (TV) and said initial temperature inside the first recovery steam generator (GRV 1 ); defining a minimum time necessary to pressurize the steam generator (GRV 1 ) by dividing the difference in temperature between the steam temperature necessary to warm up the steam turbine (TV) and the initial temperature in