Waste heat recovery power generation system and flow control method thereof

What is claimed is: 1. A waste heat recovery power generation system, comprising: a compressor configured to compress a working fluid, an output fluid of the compressor branched into a first output fluid and a second output fluid of the compressor; a heat exchanger configured to recover waste heat from waste heat gas supplied from a waste heat source, the recovered waste heat heating the working fluid, the heat exchanger comprising: a first heat exchanger receiving the first output fluid and including a working fluid outlet for passing the received first output fluid, the first heat exchanger further including a final outlet from which the waste heat gas exits the first heat exchanger; and a second heat exchanger including a working fluid inlet for receiving the first output fluid passed by the working fluid outlet of the first heat exchanger, the second heat exchanger further including a working fluid outlet for passing the working fluid received at the working fluid inlet of the second heat exchanger; a turbine configured to be driven by the working fluid heated by the recovered waste heat, the turbine including an inlet for receiving the working fluid passed by the working fluid outlet of the second heat exchanger; a recuperator configured to exchange heat between an output fluid of the turbine and the output fluid of the compressor to cool the output fluid of the turbine; a first flow control valve including a valve portion, the first flow control valve is controlled based on a measured temperature of the waste heat gas (C stream) exiting the final outlet of the first heat exchanger relative to a maximum emission temperature of a preset emission regulation condition, the valve portion coupled to the working fluid outlet of the first heat exchanger and provided between the first and second heat exchangers; and a first mixer including a first inlet receiving the first output fluid from the working fluid outlet of the first heat exchanger through the first flow control valve, a second inlet receiving the second output fluid passing through the recuperator, and an outlet for passing a mixture of the first and second output fluids to the second heat exchanger and the turbine, wherein the first flow control valve is further configured to change an amount of flow of the first output fluid to the first inlet of the first mixer based on the measured temperature such that the first flow control valve is open if the measured temperature exceeds the maximum emission temperature and is closed if the measured temperature does not exceed the maximum emission temperature. 2. The waste heat recovery power generation system of claim 1 , wherein the first heat exchanger is disposed at a low temperature side of the heat exchanger to receive the first output fluid of the compressor, and wherein the second heat exchanger is disposed at a high temperature side of the heat exchanger to receive the waste heat gas from the waste heat source and to pass the received waste heat gas to the first heat exchanger in order to exit the first heat exchanger through the final outlet. 3. The waste heat recovery power generation system of claim 2 , wherein the first output fluid branched from the output fluid of the compressor is transferred to the first heat exchanger, wherein the second output fluid branched from the output fluid of the compressor is transferred to the recuperator, and wherein the second output fluid passing through the recuperator is transferred to the second heat exchanger. 4. The waste heat recovery power generation system of claim 3 , further comprising: a first separator configured to be disposed at a downstream side of the compressor and configured to branch the output fluid of the compressor into the first output fluid and the second output fluid of the compressor, wherein the output fluid of the first heat exchanger is joined with the second output fluid passing through the recuperator at an upstream side of the second heat exchanger. 5. The waste heat recovery power generation system of claim 4 , wherein the recuperator comprises: a first recuperator; and a second recuperator, wherein the second recuperator comprises a high temperature recuperator configured to receive the output fluid of the turbine, and wherein the first recuperator comprises a low temperature recuperator configured to receive an output fluid of the second recuperator and further comprises an inlet receiving the second output fluid from the first separator. 6. The waste heat recovery power generation system of claim 5 , wherein the first recuperator is configured to receive the second output fluid of the compressor and wherein the output fluid of the first heat exchanger is joined with the second output fluid passing through the second recuperator at an upstream side of the second heat exchanger. 7. The waste heat recovery power generation system of claim 6 , further comprising: a second mixer disposed between the first recuperator and the second recuperator, the second mixer including a first inlet receiving the output fluid from the second recuperator, a second inlet receiving a third output fluid from the turbine, and an outlet for passing to the first separator a mixture of the output fluid from the second recuperator and the third output fluid from the turbine; and a second separator disposed between the outlet of the first mixer and the working fluid inlet of the second heat exchanger and configured to branch an output fluid of the first mixer into the third output fluid and a fourth output fluid, the branched fourth output fluid provided to the working fluid inlet of the second heat exchanger. 8. The waste heat recovery power generation system of claim 7 , wherein the turbine comprises: a first turbine configured to receive the third output fluid from the second separator; and a second turbine connected in parallel with the first turbine and configured to receive an output fluid of the second heat exchanger, and wherein a temperature of the third output fluid transferred to the first turbine is lower than a temperature of the output fluid of the second heat exchanger transferred to the second turbine. 9. The waste heat recovery power generation system of claim 8 , wherein the third output fluid passing through the first turbine is introduced into the second mixer, and wherein the output fluid of the second heat exchanger passing through the second turbine is mixed with the third output fluid passing through the first turbine from the second mixer through second recuperator and then is transferred to the first recuperator. 10. The waste heat recovery power generation system of claim 9 , further comprising: a storage tank configured to supply an additional working fluid; and a flow measurer is disposed at an upstream side of the compressor and an upstream side of the first heat exchanger. 11. The waste heat recovery power generation system of claim 1 , further comprising: a power generator connected to the turbine and configured to produce power; and a gear box disposed between the turbine and the power generator, configured to change an output of the turbine according to an output frequency of the power generator and configured to transfer the output of the turbine to the power generator, wherein the turbine and the compressor are connected coaxially, and wherein the compressor and the power generator are driven by the turbine. 12. The waste heat recovery power generation system of claim 1 , further comprising: a first separator configured to be disposed at a downstream side of the compressor and configured to branch the output fluid of the compressor into the first o