Power generation system having compressor creating excess air flow and heat exchanger therefor

What is claimed is: 1 . A power generation system, comprising: a first gas turbine system including a first turbine component, a first integral compressor and a first combustor to which air from the first integral compressor and fuel are supplied, the first combustor arranged to supply hot combustion gases to the first turbine component, and the first integral compressor having a flow capacity greater than an intake capacity of at least one of the first combustor and the first turbine component, creating an excess air flow; a second gas turbine system including a second turbine component, a second compressor and a second combustor to which air from the second compressor and fuel are supplied, the second combustor arranged to supply hot combustion gases to the second turbine component; a control valve system controlling flow of the excess air flow from the first gas turbine system to the second gas turbine system along an excess air flow path; and a heat exchanger coupled to the excess air flow path for exchanging heat with the excess air flow. 2 . The power generation system of claim 1 , wherein the excess air flow is supplied to a discharge of the second compressor. 3 . The power generation system of claim 1 , wherein the excess air flow is supplied to the second combustor. 4 . The power generation system of claim 1 , wherein the excess air flow is supplied to a turbine nozzle cooling inlet of the second turbine component. 5 . The power generation system of claim 1 , wherein the control valve system controls flow of the excess air flow to at least one of a discharge of the second compressor, the second combustor and a turbine nozzle cooling inlet of the second turbine component. 6 . The power generation system of claim 5 , wherein the control valve system includes a first control valve controlling a first portion of the excess air flow to the discharge of the second compressor, a second control valve controlling a second portion of the excess air flow to the second combustor, and a third control valve controlling a third portion of the flow of the excess air flow to the turbine nozzle cooling inlets of the second turbine component. 7 . The power generation system of claim 6 , further comprising at least one sensor for measuring a flow rate of at least a portion of the excess air flow, each sensor operably coupled to the control valve system. 8 . The power generation system of claim 1 , wherein an exhaust of each of the first turbine system and the second turbine system are supplied to at least one steam generator for powering a steam turbine system. 9 . The power generation system of claim 1 , wherein the heat exchanger includes an air-to-air heat exchanger to cool the excess air flow. 10 . The power generation system of claim 1 , wherein the heat exchanger includes a fuel gas heater to cool the excess air flow. 11 . The power generation system of claim 1 , wherein the heat exchanger includes a liquid cooled heat exchanger to cool the excess air flow. 12 . The power generation system of claim 11 , wherein the liquid cooled heat exchanger includes a boiler that produces a steam flow, the steam flow cooling the excess air flow. 13 . The power generation system of claim 12 , wherein, downstream of the heat exchanger, the steam flow is directed to a steam turbine system during a low load hold status of at least one of the first gas turbine system and the second gas turbine system. 14 . A power generation system, comprising: a first gas turbine system including a first turbine component, a first integral compressor and a first combustor to which air from the first integral compressor and fuel are supplied, the first combustor arranged to supply hot combustion gases to the first turbine component, and the first integral compressor having a flow capacity greater than an intake capacity of at least one of the first combustor and the first turbine component, creating an excess air flow; a second gas turbine system including a second turbine component, a second compressor and a second combustor to which air from the second compressor and fuel are supplied, the second combustor arranged to supply hot combustion gases to the second turbine component; a control valve system controlling flow of the excess air flow to at least one of a discharge of the second compressor, the second combustor and a turbine nozzle cooling inlet of the second turbine component along an excess air flow path; and a heat exchanger coupled to the excess air flow path for exchanging heat with the excess air flow, wherein the control valve system includes a first control valve controlling a first portion of the excess air flow to the discharge of the second compressor, a second control valve controlling a second portion of the excess air flow to the second combustor, and a third control valve controlling a third portion of the flow of the excess air flow to the turbine nozzle cooling inlets of the second turbine component, and wherein an exhaust of each of the first turbine system and the second turbine system are supplied to at least one steam generator for powering a steam turbine system. 15 . The power generation system of claim 14 , wherein the heat exchanger is selected from the group consisting of: an air-to-air heat exchanger to cool the excess air flow, a fuel gas heater to cool the excess air flow, and a liquid cooled heat exchanger to cool the excess air flow. 16 . The power generation system of claim 14 , wherein, downstream of the heat exchanger, the steam flow is directed to a steam turbine system during a low load hold status of at least one of the first gas turbine system and the second gas turbine system. 17 . A method comprising: extracting an excess air flow from a first integral compressor of a first gas turbine system including a first turbine component, the first integral compressor and a first combustor to which air from the first integral compressor and fuel are supplied, the first integral compressor having a flow capacity greater than an intake capacity of at least one of the first combustor and the first turbine component; directing the excess air flow to a second gas turbine system including a second turbine component, a second compressor and a second combustor to which air from the second compressor and fuel are supplied, the second combustor arranged to supply hot combustion gases to the second turbine component; and exchanging heat with the excess air flow using a heat exchanger coupled to the excess air flow path. 18 . The method of claim 17 , wherein the directing includes using a control valve system to control flow of the excess air flow to at least one of a discharge of the second compressor, the second combustor and a turbine nozzle cooling inlet of the second turbine component. 19 . The method of claim 18 , wherein the control valve system includes a first control valve controlling directing of a first portion of the excess air flow to the discharge of the second compressor, a second control valve controlling directing of a second portion of the excess air flow to the second combustor, and a third control valve controlling directing of a third portion of the flow of the excess air flow to the turbine nozzle cooling inlets of the second turbine component. 20 . The method of claim 17 , wherein the exchanging of heat includes producing a steam flow for cooling the excess air flow, and further comprising directing the steam flow, downstream of the heat exchanger, to a steam turbine s