Abstract: A system includes an intake heating system having one or more heat exchangers. The one or more heat exchangers are fluidly coupled to a steam turbine system, a gas turbine system, a carbon capture system, and a heat recovery steam generator (HRSG). The one or more heat exchangers are configured to receive steam from the HRSG, the steam turbine system, or a combination thereof. The one or more heat exchangers are also configured to receive an air. The one or more heat exchangers are also configured to place the steam in a heat exchange relationship with the air to produce a heated air and a cooled steam. The one or more heat exchangers are also configured to send the cooled steam to the carbon capture system. The one or more heat exchangers are also configured to send the heated air to one or more injection locations of the gas turbine system.

Abstract: A system includes a fuel heating system having a first heat exchanger. The first heat exchanger is fluidly coupled to a steam turbine system, a gas turbine system, a carbon capture system, and a heat recovery steam generator (HRSG). The first heat exchanger is configured to receive steam from the HRSG, the steam turbine system, or a combination thereof. The first heat exchanger is also configured to receive a fuel. The first heat exchanger is also configured to place the steam in a first heat exchange relationship with the fuel to produce a first heated fuel and a first cooled steam. The first heat exchanger is also configured to send the first cooled steam to the carbon capture system. The first heat exchanger is also configured to send the first heated fuel to the gas turbine system, a duct burner, or a combination thereof.

Abstract: A steam turbine includes an inner casing that at least partially defines the steam flow path, a passage for extending through the inner casing to at least partially define a moisture flow path out of the steam flow path, and a seal operably connected to the passage. The seal has a first position associated with a first set of operating conditions within the steam flow path and a second position associated with a second set of operating conditions within the steam flow path.

Abstract: A method of more accurately measuring steam turbine efficiency is disclosed in which the sealing steam in the steam turbine is re-routed so that a more accurate measure of steam turbine efficiency can be made. Some of the steam entering a turbine goes into the turbine's end pack and then mixes with the steam that goes through the turbine. Piping is added from one of the end pack line's to the condenser. This added line has a valve, pressure, temperature and flow measuring devices. As the valve is opened, the amount of flow going to the end pack line allowing the end pack steam mix with the steam that goes through the turbine is reduced. As the flow in this line is reduced the measured temperature at the turbine exhaust will also decrease. The amount that the valve is opened is increased until either the exhaust temperature has reached a minimum, or the enthalpy in the pipe changes from the initial enthalpy.

Abstract: A method of more accurately measuring steam turbine efficiency is disclosed in which the sealing steam in the steam turbine is re-routed so that a more accurate measure of steam turbine efficiency can be made. Some of the steam entering a turbine goes into the turbine's end pack and then mixes with the steam that goes through the turbine. Piping is added from one of the end pack line's to the condenser. This added line has a valve, pressure, temperature and flow measuring devices. As the valve is opened, the amount of flow going to the end pack line allowing the end pack steam mix with the steam that goes through the turbine is reduced. As the flow in this line is reduced the measured temperature at the turbine exhaust will also decrease. The amount that the valve is opened is increased until either the exhaust temperature has reached a minimum, or the enthalpy in the pipe changes from the initial enthalpy.