A system includes a first steam generator configured to generate a first boiler feedwater, a second steam generator configured to generate a second boiler feedwater, a common boiler feedwater configured to combine the first boiler feedwater and the second boiler feedwater to produce a common boiler
A system includes a first steam generator configured to generate a first boiler feedwater, a second steam generator configured to generate a second boiler feedwater, a common boiler feedwater configured to combine the first boiler feedwater and the second boiler feedwater to produce a common boiler feedwater, and a heater configured to receive the common boiler feedwater to heat a gas.
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1. A system, comprising: a first steam generator configured to supply a first boiler feedwater;a second steam generator configured to supply a second boiler feedwater;a first common boiler feedwater header configured to combine the first boiler feedwater and the second boiler feedwater to produce a
1. A system, comprising: a first steam generator configured to supply a first boiler feedwater;a second steam generator configured to supply a second boiler feedwater;a first common boiler feedwater header configured to combine the first boiler feedwater and the second boiler feedwater to produce a first common boiler feedwater;a second common boiler feedwater header configured to combine the first boiler feedwater and the second boiler feedwater to produce a second common boiler feedwater;a first heat exchanger configured to receive the first common boiler feedwater to transfer heat between the first common boiler feedwater and a first gas; anda controller comprising an input configured to receive a sensor feedback from a sensor measuring at least one property of the supply of the first boiler feedwater or the supply of the second boiler feedwater, wherein the controller is responsive to the sensor feedback received via the input to control at least one of the supply of the first boiler feedwater or the supply of the second boiler feedwater when the sensor feedback received via the input is indicative of non-compliance with a first threshold. 2. The system of claim 1, wherein the first steam generator comprises a first heat recovery steam generator (HRSG) and the second steam generator comprises a second HRSG. 3. The system of claim 1, comprising— a second heat exchanger configured to receive the second common boiler feedwater to transfer heat between the second common boiler feedwater and a second gas,wherein the controller is responsive to the sensor feedback received via the input to control at least one of the supply of the first boiler feedwater or the supply of the second boiler feedwater when the sensor feedback is indicative of non-compliance with the first threshold of the second boiler feedwater. 4. The system of claim 1, comprising: a first control valve configured to adjust a first flow rate of the first boiler feedwater; anda second control valve configured to adjust a second flow rate of the second boiler feedwater, wherein the controller is configured to selectively control at least one of the first control valve to control the supply of the first boiler feedwater or the second control valve to control the supply of the second boiler feedwater when the sensor feedback received via the input is indicative of non-compliance with the first threshold. 5. The system of claim 1, wherein the system comprises a second heat exchanger configured to receive the second common boiler feedwater to transfer heat between the second common boiler feedwater and a second gas, wherein the first heat exchanger comprises a gas heater and the second heat exchanger comprises a gas cooler. 6. The system of claim 1, wherein the first heat exchanger comprises a syngas heater or a syngas cooler. 7. A non-transitory, machine readable medium, comprising instructions to: control a supply of a first boiler feedwater from a first steam generator;control a supply of a second boiler feedwater from a second steam generator, wherein the first boiler feedwater and the second boiler feedwater combine using first and second boiler feedwater headers to produce first and second common boiler feedwaters, wherein a first fuel gas is cooled in a fuel gas cooler using the first common boiler feedwater to produce a cooled first fuel gas, wherein a second fuel gas is heated in a fuel gas heater using the second common boiler feedwater to produce a heated second fuel gas;receive an input from a sensor measuring at least one property of the first boiler feedwater, the second boiler feedwater, the first fuel gas, or the second fuel gas; andcontrol, in response to a sensor input, at least one of the supply of the first boiler feedwater or the supply of the second boiler feedwater, wherein the sensor input is indicative of non-compliance with a threshold for at least one property of the supply of the first boiler feedwater or the supply of the second boiler feedwater. 8. The non-transitory, machine readable medium of claim 7, wherein the sensor input indicative of the non-compliance with the threshold indicates a deviation in conditions between the first and second steam generators, wherein the deviation in conditions comprises a startup condition, or a shutdown condition, or a turn down condition, or a transition condition, or an asymmetrical load condition. 9. The non-transitory, machine readable medium of claim 7, wherein the instructions are configured to reduce a first flow rate of the first boiler feedwater to the first or second common boiler feedwater header when a first criterion is reached, or reduce a second flow rate of the second boiler feedwater when a second criterion is reached. 10. The non-transitory, machine readable medium of claim 9, wherein the first criterion comprises a first temperature of the first boiler feedwater below a first temperature threshold, or a first differential temperature between a second temperature of the second boiler feedwater and the first temperature above a differential temperature threshold; andwherein the second criterion comprises the second temperature below a second temperature threshold, or a second differential temperature between the first temperature and the second temperature above the differential temperature threshold. 11. The non-transitory, machine readable medium of claim 9, wherein the first criterion comprises a first pressure of a first high-pressure steam drum below a first pressure threshold, or a first differential pressure between a second pressure of a second high-pressure steam drum and the first pressure above a differential pressure threshold; andwherein the second criterion comprises the second pressure below a second pressure threshold, or a second differential pressure between the first pressure and the second pressure above the differential pressure threshold. 12. The non-transitory, machine readable medium of claim 9, wherein the first criterion comprises the first steam generator starting up, or shutting down, or turning down, or transitioning, or entering asymmetrical loading; andwherein the second criterion comprises the second steam generator starting up, or shutting down, or turning down, or transitioning, or entering asymmetrical loading. 13. A method, comprising: supplying a first boiler feedwater from a first steam generator;supplying a second boiler feedwater from a second steam generator;combining the first boiler feedwater and the second boiler feedwater using first and second common boiler feedwater headers to produce first and second common boiler feedwaters;cooling a first fuel gas in a fuel gas cooler using the first common boiler feedwater to produce a cooled first fuel gas;heating a second fuel gas in a fuel gas heater using the second common boiler feedwater to produce a heated second fuel gas; andcontrolling, in response to sensor input, at least one of supplying the first boiler feedwater or supplying the second boiler feedwater, wherein the sensor input is indicative of non-compliance with a threshold for at least one property of the supply of the first boiler feedwater or the supply of the second boiler feedwater. 14. The method of claim 13, wherein the sensor input indicative of the non-compliance with the threshold indicates a deviation in conditions between the first and second steam generators, wherein the deviation in conditions comprises a startup condition, or a shutdown condition, or a turn down condition, or a transition condition, or an asymmetrical load condition. 15. The method of claim 13, wherein controlling, in response to the sensor input, comprises reducing a first flow rate of the first boiler feedwater to the first or second common boiler feedwater header when a first criterion is reached, or reducing a second flow rate of the second boiler feedwater when a second criterion is reached. 16. The method of claim 15, wherein the first criterion comprises a first temperature of the first boiler feedwater below a first temperature threshold, or a first differential temperature between a second temperature of the second boiler feedwater and the first temperature above a differential temperature threshold; andwherein the second criterion comprises the second temperature below a second temperature threshold, or a second differential temperature between the first temperature and the second temperature above the differential temperature threshold. 17. The method of claim 15, wherein the first criterion comprises a first pressure of a first high-pressure steam drum below a first pressure threshold, or a first differential pressure between a second pressure of a second high-pressure steam drum and the first pressure above a differential pressure threshold; andwherein the second criterion comprises the second pressure below a second pressure threshold, or a second differential pressure between the first pressure and the second pressure above the differential pressure threshold. 18. The method of claim 15, wherein the first criterion comprises the first steam generator starting up, or shutting down, or turning down, or transitioning, or entering asymmetrical loading; andwherein the second criterion comprises the second steam generator starting up, or shutting down, or turning down, or transitioning, or entering asymmetrical loading. 19. The method of claim 13, wherein cooling the first fuel gas comprises cooling a first syngas in a first syngas cooler using the first common boiler feedwater and cooling a second syngas in a second syngas cooler using the first common boiler feedwater, wherein heating the second fuel gas comprises heating the first and second syngas cooled by the first and second syngas coolers. 20. The system of claim 1, wherein the controller is responsive to the sensor feedback received via the input of the controller to maintain compliance with the first threshold by reducing use of a non-compliant one of the first or second boiler feedwater based on a comparison of the sensor feedback with the first threshold. 21. The system of claim 1, wherein the first threshold comprises a threshold level or a threshold deviation in temperature, or pressure, or flow rate.
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