Systems and methods for Utilizing flue gas

We claim: 1. A heat recovery steam generator (HRSG) configured to receive flue gases, the HRSG comprising: an inlet duct positioned at a first end of the HRSG and configured to receive the flue gases; an outlet duct positioned at a second end of the HRSG, wherein the flue gases are configured to flow through the HRSG by flowing from the inlet duct to the outlet duct; and a steam generation system fluidly isolated from the flue gases flowing through the HRSG, wherein the steam generation system comprises: at least one economizer configured to receive liquid water at a first temperature, wherein the at least one economizer includes a plurality of economizer tubes through which the liquid water flows, wherein the flue gases flowing through the HRSG heat the liquid water within the plurality of economizer tubes from the first temperature to a second temperature greater than the first temperature; at least one evaporator configured to receive the liquid water at the second temperature from the at least one economizer, wherein the at least one evaporator includes a plurality of evaporator tubes through which the liquid water flows, wherein the flue gases flowing through the HRSG heat the liquid water within the plurality of evaporator tubes until the liquid water evaporates into steam, and wherein at least a portion of individual ones of the plurality of evaporator tubes comprise a base material including steel, and a cladding material that is resistant to corrosion at high temperatures and disposed over the base material, wherein the cladding material comprises a metal alloy ad forms an outermost layer of the individual ones of the plurality of evaporator tubes. 2. The HRSG of claim 1 , the steam generation system further comprising: at least one superheater wherein the at least one superheater includes a plurality of superheater tubes through which the steam flows, wherein the flue gases flowing through the HRSG superheat the steam within the plurality of superheater tubes, and wherein at least a portion of individual of the plurality of superheater tubes are cladded with the cladding material resistant to corrosion at high temperatures. 3. The HRSG of claim 2 , wherein the pluralities of economizer tubes, evaporator tube, and superheater tubes comprise steel. 4. The HRSG of claim 1 wherein the metal alloy comprises a Ni-Cr alloy. 5. The HRSG of claim 3 , wherein the metal alloy comprises Ferritic alloy steel. 6. The HRSG of claim 2 , wherein the cladding material resistant to corrosion at high temperatures comprises a first layer of a Ferritic alloy steel and a second layer of Inconel disposed on the first layer. 7. The HRSG of claim 2 , wherein the plurality of superheater tubes is supported by support tubes. 8. The HRSG of claim 7 , wherein the support tubes include the evaporator tubes. 9. The HRSG of claim 2 wherein the plurality of superheater tubes are oriented horizontally, wherein the at least one superheater includes one or more vertical support tubes configured to support the plurality of superheater tubes, and wherein at least a portion of the one or more vertical support tubes is cladded with the cladding material resistant to corrosion at high temperatures. 10. The HRSG of claim 9 , wherein the one or more vertical support tubes include generally horizontally projecting fins on which the superheater tubes are disposed. 11. The HRSG of claim 10 , wherein at least a portion of the fins are cladded with the cladding material resistant to corrosion at elevated temperatures. 12. The HRSG of claim 9 wherein the one or more vertical support tubes comprises one of the plurality of evaporator tubes. 13. The HRSG of claim 2 , further comprising: a plurality of sootblowers configured to remove compounds deposited on one or more the pluralities of economizer tubes, evaporator tubes, and superheater tubes, wherein at least at least one of the individual evaporator tubes and at least one of the individual superheater tubes that are cladded with the cladding material resistant to corrosion at high temperatures are adjacent to individual of the plurality of sootblowers. 14. The HRSG of claim 2 , further comprising: an exterior wall that defines an exterior surface of the HRSG; and a waterwall within the HRSG and positioned adjacent to the exterior wall, wherein— the waterwall includes at least one of the plurality of evaporator tubes the plurality of economizer tubes and the plurality of superheater tubes, and the waterwall is configured to reduce the amount of heat given off by the flue gases that can reach the exterior wall. 15. The HRSG of claim 14 wherein at least one of the plurality of superheater tubes, economizer tubes and evaporator tubes includes a curved segment and two straight segments, wherein end portions of the two straight segments are welded to the curved segment such that the curved segment fluidly couples the two straight segments together. 16. The HRSG of claim 15 wherein the end portions of the two straight segments are free of the material resistant to corrosion at high temperatures. 17. The HRSG of claim 16 wherein the end portions of the two straight segments are coated with refractory after the end portions and the curved segment have been welded together. 18. The HRSG of claim 1 wherein each of the plurality of economizer tubes is free of the material resistant to corrosion at high temperatures. 19. The HRSG of claim 1 wherein the flue gases are configured to flow in a first direction through the HRSG, and wherein the evaporator tubes are oriented in a second direction normal to the first direction, the HRSG further comprising a superheater including a plurality of superheater tubes through which the steam from the evaporator tubes flows, wherein the superheater tubes are oriented in a third direction normal to the first direction and the second direction. 20. The HRSG of claim 1 wherein the steam generation system further comprises one or more steam drums and one or more mud drums, wherein the evaporator tubes extend between and are fluidly coupled to one or more steam drums and the one or more mud drums. 21. A heat recovery steam generator (HRSG) configured to receive flue gases, the HRSG comprising: a steam generation system comprising: an economizer configured to receive a fluid at a first temperature and including economizer tubes through which the fluid flows, wherein the flue gases flowing through the HRSG heat the fluid within the economizer tubes from the first temperature to a second temperature greater than the first temperature; an evaporator configured to receive the fluid at the second temperature from the economizer, wherein the evaporator includes a plurality of evaporator tubes through which the fluid flows, wherein the flue gases flowing through the HRSG heat the fluid within the evaporator tubes until the fluid evaporates, wherein at least a portion of the evaporator tubes comprise a base material including steel, and a cladding material that is resistant to corrosion at high temperatures and disposed over the base material, wherein the cladding material comprises a metal alloy and forms an outermost layer of the portion of the evaporator tubes.