Provided is a system for controlling start-up of a combined cycle power plant that includes a gas turbine that includes a rotor, an HRSG that generates steam, a steam turbine that includes a rotor, and generators that generate electric power using rotation forces, respectively, of the rotor of the gas turbine and the rotor of the steam turbine, the system including; a sensor that measures operating states of components of the combined cycle power plant; and a controller that controls the start-up, based on the operating states, which are acquired from the sensor, in which the controller verifies one or more restrictive conditions that restrict setting of an operational value of an operational parameter for the combined cycle power plant, based on the operating states, which are acquired from the sensor, and, based on a result of the verification, sets the operational value.

A combined cycle plant, a device for controlling a combined cycle plant, and a method for starting up a combined cycle plant, wherein the time for starting up the combined cycle plant can be shortened by providing: a gas turbine having a compressor, a combustor, and a turbine; a heat recovery steam generator for generating steam by means of the exhaust heat of exhaust gas from the gas turbine; a steam turbine driven by means of the steam generated by the heat recovery steam generator; and a control device configured to set a standby load for the gas turbine during a start-up continuously to change in accordance with a change in metal temperature of the steam turbine.

Various embodiments include a system having: at least one computing device configured to monitor a combined-cycle (CC) power plant during a transient event by performing actions including: determining whether a change in an operating condition of a component of the CC power plant is unintentional, the determining including comparing control system instructions for the component of the CC power plant with a reference look-up table, the reference look-up table including correlation data for the control system instructions for the component and historical data about the operating condition of the component; and providing instructions to a control system of the CC power plant to modify the operating condition in the CC power plant in response to determining that the change in operating condition of the component is unintentional.

Systems and methods to control power plant operation via control of turbine run-up and acceleration are disclosed. According to one embodiment of the disclosure, a method of controlling a turbine in a power plant can be provided. The method may include receiving an operating pressure of a condenser associated with a power plant; receiving a rotor speed of a turbine associated with the power plant; receiving a last stage blade (LSB) protection limit for the turbine; based at least in part on the operating pressure of the condenser, the rotor speed of the turbine, and the LSB protection limit, allowing, via a control system, a run-up of the turbine. The method may further include: receiving a rotor speed gradient of the turbine; receiving one or more critical speed ranges associated with the rotor speed of the turbine; and based at least in part on the operating pressure of the condenser, the rotor speed, the rotor speed gradient, and the one or more critical speed ranges, regulating, via the control system, at least one of: the rotor speed of the turbine and the rotor speed gradient of the turbine.

In the context of electric power generation facilities, a system and method that enable control of maximum sustained rate of change in output to accommodate changing load conditions and to facilitate efficient use of system resources are disclosed. In accordance with aspects of the disclosed subject matter, a ramp rate for an electric generator source may be set, operating parameters may be monitored, rates of change or discrepancies of the operating parameters over time may be computed; and output signals may then be used selectively to control certain system components.

A steam turbine power plant includes a life consumption amount calculator configured to calculate life consumption amounts of a turbine rotor based on a value measured by a measurer, a thermal stress limit update timing determining device configured to determine a time when thermal stress limits are updated, an accumulated life consumption amount calculator configured to calculate accumulated life consumption amounts of the turbine rotor when the thermal stress limits are updated, a planned life consumption amount setting device configured to set planned life consumption amounts of the turbine rotor based on the accumulated life consumption amounts of the turbine rotor, a thermal stress limit calculator configured to calculate and update the thermal stress limits based on the planned life consumption amounts of the turbine rotor, and a plant command value calculator configured to calculate a plant command value based on the thermal stress limits.

Various embodiments include a system having: at least one computing device configured to monitor a combined-cycle (CC) power plant during a transient event by performing actions including: determining whether a change in an operating condition of a component of the CC power plant is unintentional, the determining including comparing control system instructions for the component of the CC power plant with a reference look-up table, the reference look-up table including correlation data for the control system instructions for the component and historical data about the operating condition of the component; and providing instructions to a control system of the CC power plant to modify the operating condition in the CC power plant in response to determining that the change in operating condition of the component is unintentional.

A rotational power plant using a working fluid in a closed-cycle path. The power plant has a single-shaft, compressor and turbine connected together along the path. There is heat source heat exchanger within the path moving from the compressor to the turbine. There is a heat sink and heat exchanger within the path from the turbine to the compressor. There is an Automated Fluid Inventory Management System (AFIMS). The AFIMS includes sensors to measure temperature and pressure of the working fluid at different locations within the path. There is an electronic control unit connected to the AFIMS.

Method for controlling steam admission into a steam turbine, the turbine comprising a high pressure casing, at least one reduced pressure casing and an admission steam control system, the high pressure casing and at least one reduced pressure casing comprising control valves for steam admission. The admission steam control system manages the following steps: determining a steam flow demand; elaborating a high pressure control valve opening setpoint depending on the determined steam flow demand; imposing the elaborated high pressure control valve opening setpoint to the high pressure control valves; elaborating a reduced pressure control valve opening setpoint depending on the determined steam flow demand through the dynamic interaction between high pressure control valve opening setpoint and reduced pressure control valve opening setpoint; and imposing the elaborated reduced pressure control valve opening setpoint to the reduced pressure control valves.

A steam turbine includes a boiler unit, first supply pipes, a second supply pipe, a plurality of valve units, a drain valve unit, and a controller. The controller is configured to control, before rotation of the turbine starts, an operation time and temperature of the auxiliary boiler so that the temperatures of the high-pressure turbine and the intermediate-pressure turbine are increased to the first setting temperature. The controller is configured to control, when the temperatures of the high-pressure turbine and the intermediate-pressure turbine are maintained at the first setting temperature, operation of the main boiler such that the temperature of the intermediate-pressure turbine reaches a second setting temperature while operation of the auxiliary boiler is interrupted, and control, when the temperature of the intermediate-pressure turbine is maintained at the second setting temperature, the operation of the main boiler such that steam is supplied only to the high-pressure turbine.