Systems and methods for increasing power output in a waste heat driven air brayton cycle turbocharger system

The invention claimed is: 1. A system for use with a power generator having a rotary machine including a first combustor and an exhaust passage flowing exhaust gases from the first combustor, comprising: a heat exchanger positioned in the exhaust passage; a turbocharger system, comprising: at least one first turbocharger including a first turbine fluidly coupled to an outlet of the heat exchanger, the first turbine adapted to receive gas flow from the heat exchanger, and a first compressor fluidly coupled to an inlet of the heat exchanger, the first compressor adapted to supply compressed air to the heat exchanger; at least one second turbocharger including a second turbine fluidly coupled to the outlet of the heat exchanger, the second turbine adapted to receive gas flow from the heat exchanger, and a second compressor fluidly coupled to the rotary machine, the second compressor adapted to receive gas flow from the first compressor and supply compressed air to the rotary machine; and an auxiliary, second combustor adapted to inject heated exhaust gases into a first flow path arranged between the outlet of the heat exchanger and an inlet to each of the second turbine and the first turbine; and a controller with computer readable instructions stored in memory, that when executed during operation of the power generator, cause the controller to adjust a fueling rate of fuel supplied to the second combustor for combustion based on a desired operating point for a desired power output of the rotary machine. 2. The system of claim 1 , wherein the instructions further cause the controller to increase the fueling rate of fuel supplied to the second combustor in response to the desired power output increasing. 3. The system of claim 2 , wherein the instructions further cause the controller to decrease the fueling rate of fuel supplied to the second combustor in response to a gas temperature upstream of the second turbine and first turbine being at or greater than a threshold temperature. 4. The system of claim 1 , wherein the second combustor is fluidly coupled to a fuel source and is positioned in-line with the first flow path, the second combustor receiving air for combustion from the first flow path. 5. The system of claim 1 , wherein the second combustor is fluidly coupled to a fuel source and is positioned in a second flow path that joins the first flow path between the outlet of the heat exchanger and the inlet to each of the second turbine and the first turbine. 6. The system of claim 1 , further comprising an intercooler positioned in a compressed air flow path arranged between the first compressor and the second compressor, the intercooler adapted to cool compressed air flowing from the first compressor to the second compressor. 7. The system of claim 1 , wherein the rotary machine is a gas turbine engine further including a turbine section and a compressor section separate from turbocharger system and wherein the turbine section and compressor section rotate independently from the at least one first turbocharger and the second turbocharger. 8. The system of claim 1 , further comprising an electric compressor fluidly coupled upstream of an inlet of the first compressor of the at least one first turbocharger and driven by electrical power received from an electric motor. 9. The system of claim 1 , further comprising a water injection system adapted to inject water into a third flow path arranged between the first compressor and the inlet of the heat exchanger. 10. A method for a turbocharger system for use with a power generating system, comprising: providing compressed air from a first compressor of the turbocharger system to a first combustor of a rotary machine; extracting heat from exhaust gases flowing in an exhaust path of the first combustor via a heat exchanger and transferring the extracted heat to gases flowing through a heat exchanger gas flow path of the turbocharger system; flowing heated gases from the heat exchanger gas flow path to each of a first turbine and a second turbine of the turbocharger system, the second turbine driving rotation of a second compressor and the first turbine driving rotation of the first compressor; flowing compressed gases from the second compressor to each of the first compressor and the heat exchanger; combusting fuel at a second combustor and injecting combusted gases from the second combustor into the heat exchanger gas flow path, downstream of the heat exchanger and upstream of each of the second turbine and the first turbine; adjusting a fueling rate of fuel provided to the second combustor for combustion based on a desired output of the turbocharger system; and injecting water into the compressed gases from the second compressor via a water injector positioned upstream of the heat exchanger in response to a temperature upstream of each of the second turbine and the first turbine reaching a threshold temperature. 11. The method of claim 10 , wherein adjusting the fueling rate of fuel provided to the second combustor for combustion based on the desired output includes increasing the fueling rate as the desired output increases above a baseline level achieved while not combusting fuel at the second combustor. 12. The method of claim 10 , further comprising decreasing the fueling rate in response to a temperature upstream of each of the second turbine and the first turbine reaching a threshold temperature. 13. A method for a turbocharger system for use with a power generation system, comprising: adjusting each of a rate of water injected into a first gas flow path to a heat exchanger positioned in an exhaust flow path of a rotary machine and a fueling rate to a first combustor, the first combustor injecting combusted gases into a second gas flow path arranged between an outlet of the heat exchanger and an inlet to each of a second turbine and first turbine of the turbocharger system, where the turbocharger system further includes first compressor supplying compressed air to the heat exchanger via the first gas flow path and driven by the first turbine and a second compressor driven by the second turbine and supplying compressed gases to a second combustor of the rotary machine, wherein adjusting each of the rate of water injected into the first gas flow path and the fueling rate to the first combustor is based on a desired power output of the rotary machine. 14. The method of claim 13 , wherein adjusting each of the rate of water injected into the first gas flow path and the fueling rate to the first combustor is further based on water and fuel availability of a water injection system and a fuel injection system for the first combustor, respectively. 15. The method of claim 13 , wherein adjusting each of the rate of water injected into the first gas flow path and the fueling rate to the first combustor comprises: while no water is injected into the first gas flow path, increasing the fueling rate to the first combustor as a desired power output of the rotary machine increases until a temperature upstream of the second turbine reaches a threshold; and in response to the temperature upstream of the second turbine reaching the threshold, injecting water into the first flow path. 16. The method of claim 15 , further comprising, while injecting water into the first flow path, adjusting the rate of water injected into the first gas flow path based on the temperature upstream of the second turbine and further increasing the fueling rate to the first combustor until the desired power output of the rotary machine is achieved. 17. The me