Turbocharger system for a rotary machine and method of assembling the same

We claim: 1 . A turbocharger system comprising: a low pressure turbocharger (LPT) comprising an LPT compressor and an LPT turbine coupled together via an LPT rotor, wherein said LPT compressor is configured to receive and compress ambient air, and wherein said turbocharger system is configured to divide the compressed ambient air into a heat exchanger flow and an HPT compressor inlet flow; a high pressure turbocharger (HPT) comprising an HPT compressor and an HPT turbine coupled together via an HPT rotor, wherein said HPT compressor is configured to receive and further compress the HPT compressor inlet flow, and wherein said turbocharger system is configured to channel the compressed HPT compressor inlet flow to a rotary machine as auxiliary compressed air; and a heat exchanger configured to place the heat exchanger flow into thermal communication with exhaust gases associated with the rotary machine, wherein said turbocharger system is configured to divide the heat exchanger flow discharged from said heat exchanger into parallel streams, and wherein said LPT turbine and said HPT turbine are each configured to be driven by a respective one of the parallel streams. 2 . The turbocharger system as claimed in claim 1 , wherein said LPT turbine and said HPT turbine are each configured to be driven solely by the respective one of the parallel streams after start-up of said turbocharger system. 3 . The turbocharger system as claimed in claim 1 , further comprising: an LPT energy storage unit; an HPT energy storage unit; an LPT motor/generator coupled to said LPT rotor, said LPT motor/generator is selectively operable in each of (i) a first mode, wherein said LPT motor/generator is operable to drive said LPT compressor using energy stored in said LPT energy storage unit, (ii) a second mode, wherein said LPT motor/generator is operable to transform rotational energy supplied to said LPT turbine from residual heat of the exhaust gases into energy for storage in said LPT energy storage unit, and (iii) a deactivated mode; and an HPT motor/generator coupled to said HPT rotor, wherein said HPT motor/generator is selectively operable in each of (i) the first mode, wherein said HPT motor/generator is operable to drive said HPT compressor using energy stored in said HPT energy storage unit, (ii) the second mode, wherein said HPT motor/generator is operable to transform rotational energy supplied to said HPT turbine from residual heat of the exhaust gases into energy for storage in said HPT energy storage unit, and (iii) the deactivated mode. 4 . The turbocharger system as claimed in claim 1 , wherein said HPT turbine further comprises an enhanced thrust bearing. 5 . The turbocharger system as claimed in claim 1 , further comprising an intercooler positioned in flow communication between an outlet of said LPT compressor and an inlet of said HPT compressor, wherein said intercooler is configured to decrease a temperature of the HPT compressor inlet flow. 6 . The turbocharger system as claimed in claim 1 , further comprising: at least one actuator; and a controller operatively coupled to said at least one actuator, wherein said controller is programmed to regulate said at least one actuator to regulate a work load distribution between said LPT and said HPT. 7 . The turbocharger system as claimed in claim 6 , wherein said at least one actuator comprises one of: a valve that is coupled one of (i) downstream from an outlet of said HPT turbine, and (ii) upstream from an inlet of said HPT turbine; and a geometry adjustment actuator coupled to said HPT turbine, wherein said HPT turbine comprises a variable geometry turbine. 8 . A rotary machine comprising: a compressor section configured to receive and compress intake air; a turbine section coupled to said compressor section via a rotor; a combustor section comprising at least one combustor configured to receive the compressed intake air from said compressor section, generate combustion gases, and channel the combustion gases into said turbine section such that a rotational force is imparted on said rotor, wherein the combustion gases are exhausted from said turbine section as exhaust gases; and a turbocharger system comprising: a low pressure turbocharger (LPT) comprising an LPT compressor and an LPT turbine coupled together via an LPT rotor, wherein said LPT compressor is configured to receive and compress ambient air, and wherein said turbocharger system is configured to divide the compressed ambient air into a heat exchanger flow and an HPT compressor inlet flow; a high pressure turbocharger (HPT) comprising an HPT compressor and an HPT turbine coupled together via an HPT rotor, wherein said HPT compressor is configured to receive and further compress the HPT compressor inlet flow, and wherein said turbocharger system is configured to channel the compressed HPT compressor inlet flow to at least one of said combustor section and said turbine section as auxiliary compressed air; and a heat exchanger configured to place the heat exchanger flow into thermal communication with the exhaust gases, wherein said turbocharger system is configured to divide the heat exchanger flow discharged from said heat exchanger into parallel streams, and wherein said LPT turbine and said HPT turbine are each configured to be driven by a respective one of the parallel streams. 9 . The rotary machine as claimed in claim 8 , wherein said turbocharger system is configured to channel at least a portion of the auxiliary compressed air to said turbine section, and wherein said turbine section is configured to use the portion of the auxiliary compressed air to cool components of said turbine section exposed to the combustion gases. 10 . The rotary machine as claimed in claim 8 , wherein said turbocharger system is configured to channel at least a portion of the auxiliary compressed air to an inlet of said at least one combustor, and wherein said at least one combustor is configured to channel the portion of the auxiliary compressed air into a flow path of the combustion gases. 11 . The rotary machine as claimed in claim 8 , further comprising an exhaust section coupled downstream from said turbine section, wherein said heat exchanger is positioned within said exhaust section. 12 . The rotary machine as claimed in claim 8 , wherein said LPT turbine and said HPT turbine are each configured to be driven solely by the respective one of the parallel streams after start-up of said turbocharger system. 13 . The rotary machine as claimed in claim 8 , further comprising an intercooler positioned in flow communication between an outlet of said LPT compressor and an inlet of said HPT compressor, wherein said intercooler is configured to decrease a temperature of the HPT compressor inlet flow. 14 . The rotary machine as claimed in claim 8 , further comprising: at least one actuator; and a controller operatively coupled to said at least one actuator, wherein said controller is programmed to regulate said at least one actuator to regulate a work load distribution between said LPT and said HPT. 15 . The rotary machine as claimed in claim 14 , wherein said at least one actuator comprises one of: a valve that is coupled one of (i) downstream from an outlet of said HPT turbine, and (ii) upstream from an inlet of said HPT turbine; and a geometry adjustment actuator coupled to said HPT turbine, wherein said HPT turbine comprises a variable geometry turbine. 16 . A method of assembling a turbocharger system for a rotary machine, said method comprising: coupling an ou