Regenerative thermodynamic power generation cycle systems, and methods for operating thereof

The invention claimed is: 1. A closed loop regenerative thermodynamic power generation cycle system, comprising: a pressurization device configured to pressurize a working fluid, and to deliver a working fluid stream, wherein the working fluid stream is at a first pressure (P 1 ), wherein P 1 is higher than a critical pressure of the working fluid; a first heat exchanger fluidly coupled to the pressurization device and receiving the working fluid stream from the pressurization device, and the first heat exchanger is configured to transfer heat to the working fluid stream, wherein the working fluid stream is at P 1 ; a second heat exchanger fluidly coupled to the first heat exchanger and receiving the working fluid stream from the first heat exchanger, and configured to transfer heat to the working fluid stream; and an expander fluidly coupled to the second heat exchanger and receiving the working fluid stream from the second heat exchanger, and configured to expand the working fluid stream, wherein the working fluid stream is at P 1 , to produce mechanical energy; wherein the expander comprises: a first outlet path to extract a partially expanded portion of the working fluid stream from the expander, wherein the partially expanded portion of the working fluid stream is at a second pressure (P 2 ), and to regeneratively supply the partially expanded portion of the working fluid stream to the first heat exchanger; wherein P 2 is lower than P 1 , and P 2 is higher than the critical pressure of the working fluid; and a second outlet path to provide an exhaust fluid stream from the expander wherein the exhaust fluid stream is at a third pressure (P 3 ), and to regeneratively supply the exhaust fluid stream to the second heat exchanger, wherein P 3 is lower than P 2 . 2. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , wherein the pressurization device comprises a compressor configured to compress a supercritical working fluid. 3. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , wherein the working fluid comprises carbon dioxide. 4. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , further comprising a heat source fluidly coupled between the second heat exchanger and the expander, wherein the heat source is configured to receive the working fluid stream from the second heat exchanger, wherein the working fluid stream is at P 1 , and to supply the working fluid stream to the expander. 5. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , wherein the expander includes a device selected from an axial flow turbine, a radial flow turbine, a reciprocating engine and a combination thereof. 6. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , further comprising an electrical generator coupled to the expander. 7. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , further comprising a precooler configured to supply the working fluid to the pressurization device. 8. The closed loop regenerative thermodynamic power generation cycle system of claim 1 , further comprising a flow control device to control a mass flow rate of the extraction of the partially expanded portion of the working fluid stream.