Abstract:
A method for forecasting a start period for a combined cycle power generation system including a gas turbine engine, a steam turbine and a computer control system, the method including: inputting a desired time at which the power generation system is to reach a dispatchable load; inputting a current value of a predetermined operational condition of the power generation system; the computer control system retrieving historical data relating the predetermined operational condition to prior start periods of the power generation system or a similar power generation system; the computer control system executing an algorithm which generates a forecasted start time based on the desired time, current value and the retrieve data, wherein the power generation system is predicted to reach the dispatchable load at the desired time when started at the forecasted start time, and the computer system outputting the forecasted start time to the output device.

Description:
BACKGROUND 
     The invention relates generally to combined-cycle (CC) power generation systems and, particularly, to scheduling the startup of a CC power generation system (also referred to herein as a “plant”). 
     Plants are typically operated by or for power utilities that generate power which is ultimately dispatched via central wholesale market or regulated power system operator. A power utility may generate power from one or more CC power generation systems and other power generation systems. 
     The power demand on utilities tend to vary hour-by-hour, day-by-day, season-by-season and year-to-year. The power demands from their customers are forecasted by, for example, grid operators based on historical data regarding power demand and other information such as expected weather, requests for future power by customers and events scheduled to occur that impact the demand of power. The grid operators advise the power generation operators, e.g., utilities of the forecasted power demands. Because the power demand varies, the schedules prepared by power utilities for each plant are often finalized a short time before, e.g., the day before, the power is to be generated. Once the schedule is finalized, the operators of power generation systems determine when to start the CC power generation system (plant) to provide power at the dispatchable load level when the schedule indicates that the demand for the power will occur. 
     Determining when to start a plant poses a complex and difficult scheduling problem. The startup sequence takes a plant from an off condition to the condition at which the plant produces power at a dispatchable load level. Startup sequences are typically complicated schedules involving various gas turbines, steam turbines, boilers and other systems to generate steam, and electrical generators driven by the gas and steam turbines. When a plant is stopped, the gas turbine(s) are not being provided with fuel and the steam turbine(s) are not being provided with steam. When the plant is stopped, the gas turbine(s) and steam turbine(s) cool from their last operational condition. When the plant is restarted, the duration of, or time to complete, the startup sequence is dependent to a large extent by the temperature of the steam turbine(s) when the startup sequence is initiated. 
     It would be helpful to an operator of a plant to have a tool to accurately calculate the duration of a startup sequence. The operator typically knows when his plant is committed to produce power at a dispatchable load level. Knowing an accurate startup duration, would enable the operator to start the plant at the latest possible time and using the least amount of fuel so that the dispatchable load is reached just before the plant is committed to produce power. 
     To determine when to initiate a startup sequence requires the system operator to estimate the length of time required for the sequence. Calculating an accurate, condition-based startup schedule for a CC power generation system can be a laborious and complicated task conventionally performed manually by a system operator, due to the difficulty in accurately forecasting the duration of a startup sequence. Rather than calculating an accurate, condition-based startup schedule, plant operators typically forecast the startup schedule using previously prepared templates of startup periods for a few startup conditions. The prepared startup templates conservatively predict long startup periods to ensure a predicted startup period is never shorter than any of the variations of startup sequences to which the estimated period is applied. Because they are conservative, the prepared templates of startup periods may be applied generically to a broad range of initial conditions, such as the temperature of the steam rotor at the start of a startup sequence. The prepared templates may state the startup period significantly longer than most actual startup periods. 
     While reusing existing schedule templates expedites the preparation of a new startup schedules for a new operating day or time period, schedule templates often do not yield optimal startup sequences and startup duration for any given day or time period. Moreover, previously prepared schedules may incorporate long margins of time to ensure that the various power generation components are available to suit all of the potential situations to which the schedule may be applied. These long margins result in power generation components becoming available for use, e.g., dispatchable load, up to hours before the components may be needed and unnecessarily burning fuel inefficiently at low load levels. Arriving at a dispatchable load earlier than needed results in monetary losses due to power components being operated while the components wait to be applied to generate needed power and resulting in generated power being sold at sub-optimal price levels. 
     A difficulty with the prepared estimates of the startup duration is that the plant may reach the dispatchable load level a half hour or more before the plant is scheduled to produce dispatchable power. While the plant generates power before it is scheduled to provide power, the plant consumes fuel, generates excess heat and emissions, may operate at a relatively low efficiency, and the operator may be forced to sell the power at below market prices. A plant operating at dispatchable load without a sufficient demand is undesirable. Increased cyclic duty requirements, higher fuel costs, competitive deregulated energy markets, and stringent environmental regulations create a demand for faster and more predictable startup sequences from CC power generation system operations. 
     There is a long felt need for methods and systems to easily, quickly and accurately generate schedules and forecasts to startup CC power generation systems. The need exists because the conventional manual approach to selecting one of a few prepared startup schedules results in inefficiencies, such as those due to power generating components, e.g., gas turbines and steam turbines, that reach dispatchable load levels hours before these components are actually needed. Further, the requirements that power plants bid to generate power increases the need for accurate scheduling and forecasting tools to generate startup schedules quickly and that are optimized to reduce the cost of generating power. 
     Reducing the time required to start a CC power generation system is not the only consideration when starting the system. Power generation system owners manage different startup objectives depending on local environmental regulations, energy dispatch requirements, and current fuel and energy prices. The power generation system operator may need to minimize emissions, fuel costs, or net heat rate. These considerations may affect the timing of the startup operation. Each CC power generation system may have site specific factors that affect the startup schedule. There is a long felt need for startup schedules that accurately predict the startup duration for a variety of startup operating conditions of a CC power generation system. 
     BRIEF DESCRIPTION 
     A method for forecasting a start period for a combined cycle power generation system including a gas turbine engine, a steam turbine and a computer control system including a user input and an output device, the method comprising: inputting a desired time at which the combined cycle power generation system is to reach a dispatchable load; acquiring a current value of a predetermined operational condition of the combined cycle power generation system; the computer control system executing an algorithm which generates a forecasted start time based on the desired time and current value, wherein the combined cycle power generation system is predicted to reach the dispatchable load at the desired time when started at the forecasted start time, and the computer system outputting the forecasted start time to the output device. 
     A method for forecasting a start period for a combined cycle power generation system including a gas turbine engine, a steam turbine and a computer control system, the method including: inputting a desired time at which the power generation system is to reach a dispatchable load; inputting a current value of a predetermined operational condition of the power generation system; the computer control system retrieving data from a database relating the predetermined operational condition to prior start periods of the power generation system or a similar power generation system; the computer control system executing an algorithm which generates a forecasted start time based on the desired time, current value and the retrieved data, wherein the power generation system is predicted to reach the dispatchable load at the desired time when started at the forecasted start time, and the computer system outputting the forecasted start time to the output device. 
     A method for forecasting a start period for a combined cycle power generation system including a gas turbine engine, a steam turbine and a control system including having a user input and a display, the method comprising: determining a current turbine temperature of the steam turbine temperature at a current time; determining a target time period to dispatchable load as a period from the current time to a target time at which the power generation system is to be at a predefined power output level; selecting a forecasted start time period as a period from the current time to a start time for a startup sequences of the power generation system; based on the forecasted start time period and the current turbine temperature, determining an estimated turbine starting temperature at the forecasted start time; using the estimated turbine starting temperature, determining an estimated time period for the startup sequence; summing the forecasted start time period and the estimate time period for the startup sequence to calculate a total time period; comparing the total time period to a target time period from the first time to the target time; using the forecasted start time period to determine when to start the startup sequence, if the comparison determines the total time period to be within a predetermined period of the target time period, and decrementing the forecasted start time, if the comparison indicates that the total time period is outside of the predetermined period of the target time period, and thereafter repeating the steps of the method. 
     A method for forecasting a start time for a combined cycle power generation system including a gas turbine engine (GT), at least one steam turbine (ST) and a control system including a computer having a graphical user interface (GUI) a user input and a display, the method comprising: entering into the control system a temperature of at least one of the steam turbines, wherein the temperature corresponds to a first time; determining by the control system a target time period as a period from the first time to a target time at which the power generation system is scheduled to be at a dispatchable load; selecting by the control system a forecasted start time period as a period from the first time to a start of a startup sequence for the power generation system; based on the forecasted start time period and the first temperature, determining by the controller an estimated turbine temperature to occur at the forecasted start time; based on the estimated turbine temperature, determining by the controller an estimated time period for the startup sequence; summing by the controller the forecasted start time period and the estimated time period for the startup sequence and generating an estimated total time from the first time to the end of the startup sequence; comparing by the controller the estimate total time and the target time period; the controller outputting the forecasted start time, if the controller in making the comparison determines the estimated total time period is within a predetermined period of the target time period, and decrementing by the controller the forecasted start time, if the controller determines that the estimated total time period is outside of the predetermined period of the target time period, and repeating the method. 
     A computer control system for generating a forecasted start period for a combined cycle power generation system having a gas turbine engine and a steam turbine, the computer control system comprising: a user input to receive a desired time at which the combined cycle power generation system is to reach a dispatchable load, and a current value of a predetermined operational condition of the combined cycle power generation system; an output device to output a forecasted start time, wherein the combined cycle power generation system is predicted to reach the dispatchable load at the desired time when started at the forecasted start time, a processor; electronic memory having stored thereon: data indicating the desired time, the current value; a database having historical information relating the predetermined operational condition to start periods of the combined cycle power generation system or a similar combined cycle power generation system, and an algorithm to generate the forecasted start time based on the desired time, current value and data retrieved from the database. 
     A control system for a combined cycle power generation system comprising a gas turbine and a steam turbine, the control system including a processor and an electronic memory storing a database of prior startup processes and a computer program for scheduling a start time for a future startup process, the program causing the processor to perform process steps comprising: entering as an input to the control system a current temperature of the steam turbine; determining by the control system a time period to dispatchable load period as a period from a current time to a target time at which the power generation system is scheduled to be at a dispatchable load; selecting a forecasted start time period as a period from a current time to a start of a startup process for the power generation system; based on the forecasted start time period and the current temperature of the at least one of the steam turbines, determining an estimated rotor temperature at the forecasted start time; based on the estimated rotor temperature, determining an estimated time period for a startup process which is a period initiated at the forecasted start time and ending when the power generation system reaches a predefined dispatchable load; summing the forecasted start time period and the estimated time period for the startup process to generate a total time to dispatchable load; comparing the total time to the dispatchable load to a time period from the current time to the target time; based on the forecasted start time period, determining when to start the startup process, if the controller in making the comparison determines the total time to dispatchable load to be within a predetermined period of the current time to the target time, and decrementing the forecasted start time by a predetermined period, if the controller determines in the comparison that the total time to dispatchable load is outside of the predetermined period of the current time to the target time, and repeating the method. 
    
    
     
       SUMMARY OF THE DRAWINGS 
       These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein: 
         FIG. 1  is a schematic diagram of an exemplary combined-cycle power system. 
         FIG. 2  is a screen image of a computer display screen generated by an exemplary human-machine interface (HMI) computer system for forecasting the start of a startup sequence for a combined cycle power generation system. 
         FIG. 3  is a screen image of the computer display screen showing an exemplary presentation of statistics of prior startup sequences of the combined cycle power generation system. 
         FIG. 4  is a screen image of the computer display screen showing an exemplary presentation of data stored in a database of a controller of the combined cycle power generation system, wherein the database includes historical information regarding prior startup sequences of the system and, optionally, of similar systems. 
         FIGS. 5 to 8  are exemplary flow charts of an algorithm executed by the controller for generating a forecasted start of a startup sequence for the combined cycle power generation system. 
         FIG. 9  presents timing charts showing steam turbine (ST) rotor temperature and power output during a startup period. 
     
    
    
     DETAILED DESCRIPTION 
     A human machine interface (HMI) has been developed to assist an operator of a combined cycle power generation system (also referred to as a plant) to forecasting and schedule the initiation of a startup process of the plant. The HMI may be embodied as a series of interactive computer system(s) generating screen images which enable an operator to interact with a computer software suite, software based model of the steam turbine components of the plant, and a database of historical information on startups of the plant and similar plants. The HIM may acquire information regarding a schedule for reaching dispatchable load and the current operating condition of the combined cycle power generation system from operator inputs and from sensor data, auxiliary algorithms in control systems for the power generation system and other inputs. The HIM generated screen images present to the operator possible selections and information regarding the combined cycle power generation system, such as: (i) the plant configuration, e.g., one gas turbine and one steam turbine ( 1 X 1 ), two gas turbines and one steam turbine ( 2 X 2 ), and three gas turbines and one steam turbine ( 3 X 1 ); (ii) current conditions, e.g., rotor temperature of a steam turbine; (iii) time remaining until a dispatchable load is needed from the plant; (iv) historical startup performance for recent startup operations of the plant; (v) proposed schedules and forecasts for initiating the startup sequence for the plant, and (vi) historical statistical data, such as minimums, maximums, means and standard deviations of operating parameters of the cc power system, including steam rotor temperature. 
     The HMI provides a tool for estimating a time period needed to perform a startup sequence based on an estimated start condition of the plant. The HMI tool calculates a period for the startup sequence based on a known starting condition, such as the initial rotor temperature for a steam turbine in the system. To determine the known starting condition, the HMI tool performs a calculation to estimate the amount of time for a startup sequence of the plant enables the HMI tool to forecast when to initiate the startup sequence to cause the plant to reach a dispatchable power level when the demand for the power from the plant is scheduled to occur. The outputs of the HMI screen are presented in a way that makes it easy for the plant operator to communicate the inputs such as start time and fuel burn needed by a dispatcher, grid operator or power trader. A technical effect of the, the HMI computer system is to generate a forecasted start time for a combined cycle power generation system which is the “latest” time at which the system can be started and reach the dispatchable load at the scheduled time to provide the requested power to, for example, a power grid. For example, the forecasted start time may cause the power generation system to reach the dispatchable load no more than three to five minutes before the scheduled time to provide the requested power. 
     The heating of the turbine during the startup sequence is a dominant factor in determining the time required for a startup sequence of the plant. Steam turbines require a relatively long start period, as compared to the start periods needed to start a gas turbine and other components of CC power generation system. By estimating the time to start a steam turbine, the period of a startup sequence can be estimated. The time needed to start a steam turbine can be determined based on correlations between current conditions and historical data or modeled, such as by using a look-up table correlating rotor temperatures to startup time period. A model of the steam turbine may also be a set of mathematical algorithms that accurately predict operating conditions of the turbine based on predefined input conditions. Using the model of the steam turbine, the period of a startup sequence can be predicted based on the initial temperature of the steam turbine at the initiation of the startup sequence. Moreover, a model of the steam rotor may be used to predict future turbine temperature 
       FIG. 1  is a schematic diagram of a combined cycle (CC) power generation system (plant)  10  comprising one or more gas turbine engines (GTs)  12 , a heat recovery steam generator (HRSG)  14 , one or more steam turbines (ST)  16 , a steam condenser  23  and one or more electrical generators  18  that output electrical power to a power demand, such as to an electrical utility grid  20  and customers connected to the grid. 
     A control system  22  monitors and controls the CC power generator system by sensing operating conditions of the components of the system, such as the rotor temperature of the steam turbine(s), steam inlet and outlet pressures to the HRSG and to the steam turbines, power output by each of the gas and steam turbines, fuel flow and consumption by the gas turbines and power output of the generator. The control system captures, stores and provides data regarding the current and historical operating conditions of the CC power generation system. 
     The control system  22  also provides commands to the CC power generation system, such as to adjust fuel flow to each of the gas turbines, initiating a start sequence in the gas turbines and steam turbines, and connecting the electrical power outputs of the generators to the utility grid after the system reaches a dispatchable load level. For example, the control system may generate commands that start the CC power generation system according to a startup sequence inputted or approved by a system operator interacting with the control system. 
     The control system  22  may be a computer control system having a central processing unit (CPU), computer memory storing software programs such as a software control suite, a user display screen  24 , user input devices  26 , such as a keyboard, and communication modules that receive sensor signals from sensors monitoring the CC power generation system and data generated regarding the system. 
       FIG. 2  is a screen image  30  of a computer display screen  24  showing an exemplary human-machine interface (HMI) for calculating a proposed start time for a combine cycle power generation system. The screen image  30  provides information and selectable options for calculating a recommended start time for a startup sequence of the plant. The screen image includes selectable navigation buttons  32  that an operator, using the input devices  26 , can select to switch screens between the start period calculation screen  30  and a performance statistics screen, shown in  FIG. 3 . In addition, the navigation buttons  32  are used to set the plant configuration (see button bars labeled  1 X 1  and  2 X 1 ) for inputting to the computer system the plant configuration of the plant for which a start time is to be forecasted. 
     The screen image  30  presents the initial plant conditions inputted to the computer system and used to forecast a start time for the startup sequence of the plant. The initial plant conditions include the plant configuration  34  (which may be manually inputted), the current temperature  36  of a steam turbine (which may be automatically or manually inputted based on temperature sensor data detecting the rotor temperature on the steam turbine), and a target time  38  which is when the plant is scheduled to reach a dispatchable load level. 
     After the operator confirms that the input conditions  34 ,  36  and  38  are correct as displayed on the screen image, the operator activates the calculation screen button  40  to cause the computer system to apply the input conditions to forecasting algorithm and generate a forecasted start time  42  to initiate the startup sequence of the plant. The start time forecast  42  is displayed on the screen image  30 . In addition, the screen image may display the expected rotor temperature  44  of the steam turbine, e.g., the reheat (RH) steam turbine, in the plant at the initiation of the startup sequence and display the amount of time remaining  46 , e.g., 145.5 minutes, after the startup sequence is initiated. 
     The screen display  30  may also display historical information  48  of the same plant and similar plants executing startup sequences while operating in the same configuration as selected by the navigation buttons  32  and having an initial rotor temperature as shown in rotor temperature display  44 . The historical information  48  may include comparative start data  50  of the average period for the startup sequence for the plant(s) under similar conditions, such as, a range  51  of steam rotor temperatures and plant configuration. The range  51  may be automatically selected as corresponding to the estimated rotor temperature  44  at the forecasted start  42  of the startup sequence. The historical information may also include a display of the number count  52  of startup sequences performed under similar conditions, and the range  54  of the length of time for the startup sequences performed under similar conditions. 
       FIG. 3  is a screen image  60  showing statistics on historical startup processes of the plant. To view the statistics the operator first inputs the plant configuration, e.g.,  1 X 1  or  2 X 1 , using the buttons  34  and selects a temperature range pull-down menu  62  corresponding to the starting steam turbine rotor temperature, e.g., 600-700 degrees Fahrenheit. The selected temperature range may be used as the temperature range  51  in the screen image  30 . Alternatively, the temperature range  51 ,  62  may be automatically selected by the computer as a range including the estimated temperature of the rotor of the steam turbine at the start of the startup sequence for the plant. This screen is tailored to plant engineers and managers that seek to troubleshoot, benchmark and optimize start times. 
     Upon selection of a temperature range  62  and the plant configuration  34 , the computer system displays charts of statistics  64  of historical startup sequences performed by the plant where the startup began with a steam rotor temperature in the range  62 . The charts  64  may be arranged to show startup data for various startup parameters. For example, the statistics may show the startup data in terms of time, e.g., minutes, and fuel consumed, e.g., such as a million British Thermal Units (MMBTU). 
     The startup data may also be divided in the charts  64  between “pre-IPC” and “IPC to Load”. The period pre-IPC refers to the portion of the startup period that begins with the start of the startup period and ends when the steam turbine is placed on inlet pressure control (IPC). The period pre-IPC is often subject to manual settings and thus varies due to adjustments made by the operator of the plant. The period from IPC to load (which is dispatchable load) tends to be automated and not subject to manual settings of the operator. The statistics that are presented in the chart  64  may represent averages (EWMA) for several startup processes having the same plant configuration ( 1 X 1  or  2 X 1 ) and rotor temperature at start. In addition to averages, the presented statistics may include minimum and maximum times and fuel consumed for the historical starts. In addition, the presented statistics may include data for startup processes that where scheduled with an automated forecaster, such as disclosed herein (“Stage 2 ”, and with conventional manual startup scheduling techniques (“Stage 1 ”) as shown in  FIG. 9 . The startup processes may include two or more stages. The two stages disclosed here are for illustrative purposes in  FIG. 9 . 
     The screen display  60  may also include graph selection buttons  66  for selecting graphs  68  showing various arrangements of historical plant startup data such as the total period of a startup sequence correlated to the steam turbine rotor temperature at the start of the startup sequence. The data correlating rotor temperature at the start of the startup sequence may be graphed with respect to the period of the start time to pre-IPC and the period of IPC to dispatchable load. A legend  70  may provide a text explanation of the graphs  69  and other data presented on the screen image  60 . 
     The start of the startup sequence for the plant may be defined as when the lead gas turbine (GT) is started. The screen image  60  may also display an estimate of time and fuel and time savings  72  due to using the automated forecaster, such as disclosed herein, as compared to conventional manual startup scheduling techniques. 
       FIG. 4  is a screen image  80  showing the database fields of a database  82  (See  FIG. 1 ) of startup processes for the plant and possibly similar plants. The database may have data fields for various temperature ranges  84  for the rotor temperature of the steam turbine at the start of a startup sequence. The temperature ranges  84  may correspond to the temperature ranges shown in  FIG. 2  at  51  and in  FIG. 3  at  62 . The database fields may also include additional fields  86  for data regarding the start date of each startup sequence represented in the database; the rotor temperature for one or more of the steam turbines in the plant, such as the reheat and high pressure steam turbines; the time periods, e.g., in minutes, from start to IPC, from IPC to dispatchable load and the total time for the startup process; the amounts of energy consumed (MMBTU) from start to IPC, from IPC to dispatchable load and the total energy consumed during the startup process, and the peak rotor stress during the startup process. In addition, screen display  80  may include data entry fields  88  to allow the operator to enter data from a particular startup process permanently into the database. 
       FIGS. 5 and 6  show an exemplary flow chart of an algorithm  100  to forecast a period needed to start a combine cycle (CC) power generation system. At the start of the algorithm, data  102  is collected regarding initial conditions of the CC power generation system (plant), for example: (i) the configuration of the CC power generation system, e.g. a  1 X 1  and  2 X 1  configuration of gas turbines in and steam turbines; (ii) the current metal temperature of the steam turbine, e.g., the metal temperature of a first row of turbine buckets in a reheat steam turbine, and (iii) the amount of time until the CC power generation system is to produce power at a dispatchable load level. 
     The rotor temperature of the steam turbine may be selected as an input condition because the steam turbine(s) has a slow rate of heating as compared to other components in the CC power generation system. The steam turbine(s) require the most time to heat to a temperature at which the CC power generation system produces dispatchable power for the intended load. These initial conditions entered in step  102  may be manually entered into a memory of the computer system executing the algorithm  100  and which will generate the forecast for the start period of the CC power generation system. Otherwise, the initial plant conditions may be automatically obtained by the computer system based on data captures from sensors monitoring the CC power generation system and for data sent to the computer, such as regarding a timing schedule of when a power load will require dispatchable load power from the CC power generation system. 
     The forecasted start time is the time from the current time to when steam turbine the CC power generation system is to be started, such that the system reaches the dispatchable load level when the load is scheduled to be delivered to the power grid. Initially, in step  104 , the forecasted start period (A) is set to equal the remaining period (D) until the plant is scheduled to provide a dispatchable load to the grid. This initial setting for the start period (A) is not a realistic actual start time as the plant does to immediately reach dispatchable load. 
     The initial setting for the start period (A) is used to initiate a calculation  109  to determine a practical start time that will allow the plant to reach its dispatchable power load level when the plant is scheduled to deliver the power load level. The calculation  109  determines whether the forecasted start period (A) will result in the plant reaching its dispatchable load power level when the time period (D) expires. The remaining period (D) is the period remaining until the plant is scheduled to provide the dispatchable load power. If the forecasted period (A) does not result in the plant reaching its dispatchable load at the expiration of time period (D), the forecasted time is adjusted, e.g., decremented by five minutes, in step  111 . 
     In the calculation  109 , a comparison  106  is made between a forecasted time period (A+Z) until the plant will reach the dispatchable power level to the remaining period (D) until the plant is scheduled to reach that power level. If the forecasted time period (A+Z) is within a predetermined time period  106 , e.g., within five (5) minutes, of the remaining period (D), the start period (A) is acceptable and the algorithm  100  calculates an exact start time as the start period (A) added to the current time. 
     The calculation  109 , at step  110 , determines a period (X) as the sum of the metal cooling time period (M) and the subsequent startup duration to estimate the duration from the current time to the plant reaching a dispatchable load. During the cooling time period (M), the steam turbine continues to cool and the metal temperature of the rotor in the steam turbine falls to the current rotor temperature. The time “M” is the number of hours taken by the steam turbine to cool to the current rotor temperature. 
     To estimate the period (Z) for the startup sequence, the algorithm uses the estimated rotor temperature (Y)  112  of the steam turbine when the startup sequence is initiated. To estimate the rotor temperature (Y) when the startup sequence is initiated, the algorithm  100  determines the rotor metal temperature drop due to cooling of the rotor from its current rotor temperature to the rotor temperature at the estimated start time for the startup sequence. 
     The cooling period (X) is used to determine a predicted metal temperature (Y) at the start time (A), in step  112 . The determination of metal temperature (Y) may use a look-up table stored in computer memory that correlates a particular metal temperature, e.g., the first row of turbine blades in the reheat (RH) steam turbine. The look-up table or model of the steam turbine/rotor may be prepared based on historical data of the plant regarding rotor cooling times and temperatures in the RH steam turbine. 
     In step  114 , a forecasted time period for startup sequence (Z) is determined based on the predicted metal temperature (Y) as the start time (A). The time period for startup (Z) is the period from the start time (A) to the CC power generation system reaching the dispatchable load power level. The forecasted startup time period (Z) may be determined from a look-up table stored in the computer of the CC power generation system that correlates the forecasted startup time period (Z) to the metal temperature (Y) at the start time (A), which is the initiation of the startup time period. The look-up table for determining the startup time period (Z) may be developed based on empirical data from earlier startup procedures with the same or similar CC power generation systems having the same configuration, e.g.,  1 X 1  or  2 X 1 . 
     When, in step  106 , a start time (A) is determined that results in a startup time period (A) that is within a predetermined range of the time (D) when the CC power generation system is scheduled to deliver the dispatchable load, the calculation  109  is completed and an exact start time is determined in step  108 . The exact start time is determined based on the current time and the time to start (A). The exact start time is displayed, in step  118 , to the system operator, such as by being presented in the screen image shown in  FIG. 2 . In addition, the display may show the metal temperature (Y) at the time of start and the time until the CC power generation system reaches the dispatchable load level. The generation and display of the start time, predicted metal temperature and total time to dispatchable load are technical effects achieved with the algorithm  100 . 
     If the forecasted start time (A) is not within a predetermined period, e.g., within 5 minutes of the time (D) at which the dispatchable load is scheduled, (step  106 ) the calculation  109  is repeated, in step  116 . Before repeating the calculation, the start time (A) decremented, such as a predetermined amount of five (5) minutes, in step  111 . By decrementing the calculation of the start time (A) and repeating the calculation  109 , the start time (A) will be adjusted until the start time (A) results in a startup procedure that results in the CC power generation system reaching the dispatchable load level at the time scheduled for the dispatchable load to be delivered to the power grid or other customer facility. 
       FIGS. 7 and 8  are an exemplary flow chart of an algorithm  120  to determine a forecasted start time (A)  122  for a CC power generation system (plant). The current steam rotor temperature  124  and initial estimated start time (A)  126  are provided as input data to the computer and applied to a steam turbine rotor model  128  electronically stored in memory of the computer for the plant. The steam turbine rotor model  128  simulates the metal cooling rates of the rotor of a steam turbine in the plant, such as the reheat (RH) steam turbine. The model  128  may be a look-up table that correlates the rotor metal temperature at various times, e.g., every five minutes, during a steam turbine cooling period. Based on the input data  124 ,  126 , of the current rotor temperature and the estimated time to start the plant, the computer access the steam turbine rotor model to determine a predicted temperature (Y)  130  of the rotor at the start of the system. 
     The predicted rotor temperature (Y)  130  at the start of the startup sequence and the plant configuration ( 1 X 1  or  2 X 1 )  133  are inputs used to access a database  132  of historical starts of the plant starts for the same plant or for similar plants. The database has information regarding the time period from the start of a plant startup operation to when the plant reaches dispatchable load. The database may include information on the most recent startup procedures. Data on older startup periods may be deleted from the database, if the computer memory storing the database lacks sufficient memory capacity. The computer by accessing the database  132  generates a predicted startup time period (Z)  134  for the startup sequence, where the period (z) is from start of the plant to when the plant reaches a dispatchable load. The startup period (Z) may be based on a mean startup sequence behavior based on earlier startup sequences of the plant performed when the plant has the same configuration and started at a similar steam turbine rotor temperature. 
     The predicted startup time period  134  is added, in step  136 , to the current estimated start time to yield a summation of the forecasted start time and the startup period. The summation of the total time until the plant is forecasted to reach dispatchable load  140  is compared  142  to a target time (D)  144  at which the plant is scheduled to reach the dispatchable load level. 
     If the difference between the estimated total time (T)  140  and the target time (D)  144  is within a predefined period of tolerance (a)  146 , the current estimated start time (A)  140  is output by the computer to an associated display device  148  which presents the forecasted start time  122  as the current estimated start time (A)  138  in terms of the month, date and year and time in hours and minutes (MM/DD/YY HH:MM)  150  at which the plant should be started and the startup period begun. In addition, the computer may output the predicted rotor temperature (Y) of the steam turbine at the start of the startup sequence and the estimated total time (T) from a current time to when the plant reaches the dispatchable power load level. 
     The period of tolerance (α)  146  may be an input that is manually set and defines a period of time, e.g., 5 minutes to 30 minutes, around the target time during which it is acceptable for the plant to reach dispatchable load level. 
     If, in step  142 , the difference between the target time period (D)  144  and current estimated total time to dispatchable load (T)  140  is beyond the tolerance period  146 , the current estimated time before the plant starts is decremented, e.g., by five minutes, to generate a new current estimated time (A)  138  until the plant starts. The period of tolerance (α)  146  may be the same period used to decrement the estimated start time (A) in step  152 . Using the new current estimated time before the plant starts (A)  138 , the algorithm  120  is repeated to generate a new estimated time until the plant reaches dispatchable load. The current estimated start time (A) will be sequentially decremented and the algorithm repeated, until the total estimated time (T) until the plant reaches dispatchable load is within the tolerance period of the target time (D) for the plant to be at dispatchable load. 
       FIG. 9  presents time charts showing an exemplary startup sequence for a combined cycle power generation system. As shown in the figure, the sequence begins when the power generation system is shut-down  160  at which point the power output of the entire system or at least just the gas turbine(s) (GT) falls to zero. After shut-down, the steam turbine (ST) rotor temperature gradually cools  162  because hot gases are not passing through the ST. The rotor continues to cool until hot gasses from the gas turbine is applied to steam turbine at which point  164  the steam turbine begins to rotate or “roll”. Prior to the ST roll point, at least the lead gas turbine is started  166 . After the ST roll point, the ST rotor temperature begins to increase  167  along with the power output  168  of the CC power generation system. As the ST rotor temperature reaches the steady operating level  170 , the system reaches a dispatchable load level  172 . 
     An operator desires to have the CC power generation system reach the dispatchable load level when the system is scheduled to deliver dispatchable power. The operator knows the current time, the ST rotor temperature at the current time and when the system is scheduled to deliver the dispatchable power. This information is inputted to the HMI tool which applies the algorithms disclosed herein to determine when to start at least the lead gas turbine (period A). 
     While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur by those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as they fall within the true spirit of the invention.