Systems and methods for adjusting floor pressure levels to improve combined cycle plant startup

What is claimed is: 1 . A method for adjusting floor pressure levels of HRSG steam circuits, said method comprising: receiving a plurality of measured plant operating values associated with a HRSG steam circuit; identifying a plurality of candidate pressure levels for use in pressurizing the HRSG steam circuit; determining a calculated steam velocity level for each of the plurality of candidate pressure levels; identifying a steam velocity limit for a steam piping section of the HRSG steam circuit; selecting a lowest pressure level of the plurality of candidate pressure levels, wherein the lowest pressure level is associated with a determined calculated steam velocity level that does not exceed the identified velocity limit; and pressurizing the HRSG steam circuit to the selected lowest pressure level. 2 . The method of claim 1 , further comprising: opening at least one steam bypass valve associated with the HRSG steam circuit upon pressurizing the HRSG steam circuit to the selected lowest pressure level. 3 . The method of claim 2 , further comprising: receiving a plurality of pipe and steam temperature data associated with each section of the HRSG steam circuit supply to each steam turbine section; identifying an admission temperature level associated with the steam turbine section; determining that a steam temperature level meets the admission temperature level, the steam temperature level associated with the plurality of steam temperature data; and initiating steam admission to the steam turbine section. 4 . The method of claim 1 , further comprising: identifying a pressure buffer associated with the HRSG steam circuit; and adjusting the selected lowest pressure level with the pressure buffer. 5 . The method of claim 1 , further comprising: monitoring the measured plant operating values associated with the HRSG steam circuit to identify a variance between actual operating values and target operating values; and dynamically adjusting the selected lowest pressure level based on the identified variance. 6 . The method of claim 1 , further comprising: identifying a projected drum swell associated with the selected lowest pressure level; and validating that the drum swell does not exceed a drum swell threshold. 7 . The method of claim 1 , further comprising: identifying a performance impact on a mist eliminator associated with steam-water separation efficiency at the selected lowest pressure level; and validating that the performance impact does not exceed a steam-water separation efficiency threshold. 8 . A pressure controlling computing device for adjusting floor pressure levels of HRSG steam circuits, said pressure controlling computing device comprising a processor in communication with a memory, said processor is programmed to: receive a plurality of measured plant operating values associated with a HRSG steam circuit; identify a plurality of candidate pressure levels for use in pressurizing the HRSG steam circuit; determine a calculated steam velocity level for each of the plurality of candidate pressure levels; identify a steam velocity limit for a steam piping section of the HRSG steam circuit; select a lowest pressure level of the plurality of candidate pressure levels, wherein the lowest pressure level is associated with a determined calculated steam velocity level that does not exceed the identified velocity limit; and pressurize the HRSG steam circuit to the selected lowest pressure level. 9 . The pressure controlling computing device of claim 8 , further configured to: open at least one steam bypass valve associated with the HRSG steam circuit upon pressurizing the HRSG steam circuit to the selected lowest pressure level. 10 . The pressure controlling computing device of claim 9 , further configured to: receive a plurality of pipe and steam temperature data associated with each section of the HRSG steam circuit supply to each steam turbine section; identify an admission temperature level associated with the steam turbine section; and determine that a steam temperature level meets the admission temperature level, the steam temperature level associated with the plurality of steam temperature data; initiate steam admission to the steam turbine section. 11 . The pressure controlling computing device of claim 8 , further configured to: identify a pressure buffer associated with the HRSG steam circuit; and adjust the selected lowest pressure level with the pressure buffer. 12 . The pressure controlling computing device of claim 8 , further configured to: monitor the measured plant operating values associated with the HRSG steam circuit to identify a variance between actual operating values and target operating values; and dynamically adjust the selected lowest pressure level based on the identified variance. 13 . The pressure controlling computing device of claim 8 , further configured to: identify a projected drum swell associated with the selected lowest pressure level; and assess projected drum swell, and adjust selected lowest pressure level upwards as necessary to satisfy a drum swell threshold. 14 . The pressure controlling computing device of claim 8 , further configured to: identify a performance impact on a mist eliminator associated with steam-water separation efficiency at the selected lowest pressure level; and assess the mist eliminator performance and adjust selected lowest pressure level upwards as necessary to satisfy the mist eliminator performance threshold. 15 . At least one non-transitory computer-readable storage media for adjusting floor pressure levels of HRSG steam circuits having computer-executable instructions embodied thereon, wherein when executed by at least one processor of a pressure controlling computing device, the computer-executable instructions cause the processor to: receive a plurality of measured plant operating values associated with a HRSG steam circuit and its steam turbine section; identify a plurality of candidate pressure levels for use in pressurizing the HRSG steam circuit; determine a calculated steam velocity level for each of the plurality of candidate pressure levels; identify a steam velocity limit for a steam piping section of the HRSG steam circuit; select a lowest pressure level of the plurality of candidate pressure levels, wherein the lowest pressure level is associated with a determined calculated steam velocity level that does not exceed the identified velocity limit; and pressurize the HRSG steam circuit to the selected lowest pressure level. 16 . The at least one non-transitory computer-readable storage media of claim 15 , wherein the computer-executable instructions further cause the processor to: open at least one steam bypass valve associated with the HRSG steam circuit upon pressurizing the HRSG steam circuit to the selected lowest pressure level. 17 . The at least one non-transitory computer-readable storage media of claim 16 , wherein the computer-executable instructions further cause the processor to: receive a plurality of pipe and steam temperature data associated with each section of the HRSG steam circuit supply to each steam turbine section; identify an admission temperature level associated with the steam turbine section; determine that a steam temperature level meets the admission temperature level, the steam temperature level associated with the plurality of steam temperature data; and initiate steam admission to the steam turbine section. 18 . The at least o