Optimization of Operating Profit for the FEED of the PZAS Process for CO2 Capture on a 460 MW NGCC
A rating model of Piperazine with the Advanced Stripper (PZAS) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance data. Surrogate rating models were built and used to optimize the variable profit of the system, subject to natural gas and electricity pric...
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| Published in | Industrial & engineering chemistry research Vol. 62; no. 35; pp. 13911 - 13921 |
|---|---|
| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
American Chemical Society
22.08.2023
American Chemical Society (ACS) |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0888-5885 1520-5045 1520-5045 |
| DOI | 10.1021/acs.iecr.3c00874 |
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| Abstract | A rating model of Piperazine with the Advanced Stripper (PZAS) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance data. Surrogate rating models were built and used to optimize the variable profit of the system, subject to natural gas and electricity price, at a fixed value for CO2 of $80/tonne. Several process constraints were considered between ambient temperatures of 4.4 and 40.5 °C. Lower lean loading resulted in a lower reboiler heat duty of about 2.2 GJ/tonne. Lean loading at 0.2 mol/equiv. of N was sufficient at an ambient temperature of 4.4 °C to maximize variable profit. Solvent precipitation was avoided even at a low lean loading (0.18 mol/mol) in the absence of a trim cooler for the lean solvent between the absorber and the cold cross exchanger. Optimal CO2 removal was always higher than the design case removal of 90% and achieved a peak of 93.6% for a 4.4 °C ambient temperature. Lean solvent rate was a significant driver of profitability. The maximum capacity of the compressor was a significant constraint on profitability. Increasing compressor capacity by 20–30% could increase variable profit by about 21% in the case of 0.18 lean loading at 4.4 °C ambient temperature. This increase in profit was lower at a higher ambient temperature and higher lean loading. The breakeven gas price was $4.6/MMBtu at a high lean loading of 0.22 mol/mol. Below this value, profit was maximized by increasing the boiler heat rate. Above this value, profit could not be increased by burning additional natural gas, requiring a reduction in boiler heat rate and, consequently, specific heat duty. At lower lean loadings (0.2 and 0.18 mol/mol), this transition in heat duty was not observed due to the lower heat duty. As the ambient temperature increased, a similar trend in heat duty was observed at 0.22 lean loading, but the transition to a lower heat duty occurred earlier at $4/MMBtu. This was because of the lower CO2 production at higher ambient temperatures, making the process unprofitable at a gas price higher than $3/MMBtu unless the heat duty of the stripper and natural gas boiler is steeply decreased. |
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| AbstractList | A rating model of Piperazine with the Advanced Stripper (PZAS) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance data. Surrogate rating models were built and used to optimize the variable profit of the system, subject to natural gas and electricity price, at a fixed value for CO2 of $80/tonne. Several process constraints were considered between ambient temperatures of 4.4 and 40.5 °C. Lower lean loading resulted in a lower reboiler heat duty of about 2.2 GJ/tonne. Lean loading at 0.2 mol/equiv. of N was sufficient at an ambient temperature of 4.4 °C to maximize variable profit. Solvent precipitation was avoided even at a low lean loading (0.18 mol/mol) in the absence of a trim cooler for the lean solvent between the absorber and the cold cross exchanger. Optimal CO2 removal was always higher than the design case removal of 90% and achieved a peak of 93.6% for a 4.4 °C ambient temperature. Lean solvent rate was a significant driver of profitability. The maximum capacity of the compressor was a significant constraint on profitability. Increasing compressor capacity by 20–30% could increase variable profit by about 21% in the case of 0.18 lean loading at 4.4 °C ambient temperature. This increase in profit was lower at a higher ambient temperature and higher lean loading. The breakeven gas price was $4.6/MMBtu at a high lean loading of 0.22 mol/mol. Below this value, profit was maximized by increasing the boiler heat rate. Above this value, profit could not be increased by burning additional natural gas, requiring a reduction in boiler heat rate and, consequently, specific heat duty. At lower lean loadings (0.2 and 0.18 mol/mol), this transition in heat duty was not observed due to the lower heat duty. As the ambient temperature increased, a similar trend in heat duty was observed at 0.22 lean loading, but the transition to a lower heat duty occurred earlier at $4/MMBtu. This was because of the lower CO2 production at higher ambient temperatures, making the process unprofitable at a gas price higher than $3/MMBtu unless the heat duty of the stripper and natural gas boiler is steeply decreased. A rating model of PZAS (Piperazine with the Advanced Stripper) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance data. Surrogate rating models were built and used to optimize variable profit of the system subject to natural gas and electricity price at a fixed value for CO2 of $\$80$/tonne. Several process constraints were considered between ambient temperatures of 4.4 and 40.5 °C. Lower lean loading resulted in lower reboiler heat duty of about 2.2 GJ/tonne. Lean loading at 0.2 mol/equiv N was sufficient at an ambient temperature of 4.4 °C to maximize variable profit. Solvent precipitation was avoided even at low lean loading (0.18 mol/mol) in the absence of a trim cooler for the lean solvent between the absorber and the cold cross exchanger. Optimal CO2 removal was always higher than the design case removal of 90% and achieved a peak of 93.6% for 4.4 ºC ambient temperature. Lean solvent rate was a significant driver of profitability. The maximum capacity of the compressor was a significant constraint on profitability. Increasing compressor capacity by 20–30% could increase variable profit by about 21% in the case of 0.18 lean loading at 4.4 °C ambient temperature. Furthermore, this increase in profit was lower at higher ambient temperature and higher lean loading. The breakeven gas price was $\$4.6$/MMBtu at high lean loading of 0.22 mol/mol. Below this value, profit was maximized by increasing the boiler heat rate. Above this value, profit could not be increased by burning additional natural gas, requiring a reduction in boiler heat rate and consequently, specific heat duty. At lower lean loading (0.2, 0.18 mol/mol), this transition in heat duty was not observed due to the lower heat duty. As the ambient temperature increased, a similar trend in heat duty was observed at 0.22 lean loading, but the transition to lower heat duty occurred earlier at $\$4$/MMBtu. This was because of the lower CO2 production at higher ambient temperature, making the process unprofitable at a gas price higher than $\$3$/MMBtu unless the heat duty of the stripper and natural gas boiler is steeply decreased. A rating model of Piperazine with the Advanced Stripper (PZAS) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance data. Surrogate rating models were built and used to optimize the variable profit of the system, subject to natural gas and electricity price, at a fixed value for CO₂ of $80/tonne. Several process constraints were considered between ambient temperatures of 4.4 and 40.5 °C. Lower lean loading resulted in a lower reboiler heat duty of about 2.2 GJ/tonne. Lean loading at 0.2 mol/equiv. of N was sufficient at an ambient temperature of 4.4 °C to maximize variable profit. Solvent precipitation was avoided even at a low lean loading (0.18 mol/mol) in the absence of a trim cooler for the lean solvent between the absorber and the cold cross exchanger. Optimal CO₂ removal was always higher than the design case removal of 90% and achieved a peak of 93.6% for a 4.4 °C ambient temperature. Lean solvent rate was a significant driver of profitability. The maximum capacity of the compressor was a significant constraint on profitability. Increasing compressor capacity by 20-30% could increase variable profit by about 21% in the case of 0.18 lean loading at 4.4 °C ambient temperature. This increase in profit was lower at a higher ambient temperature and higher lean loading. The breakeven gas price was $4.6/MMBtu at a high lean loading of 0.22 mol/mol. Below this value, profit was maximized by increasing the boiler heat rate. Above this value, profit could not be increased by burning additional natural gas, requiring a reduction in boiler heat rate and, consequently, specific heat duty. At lower lean loadings (0.2 and 0.18 mol/mol), this transition in heat duty was not observed due to the lower heat duty. As the ambient temperature increased, a similar trend in heat duty was observed at 0.22 lean loading, but the transition to a lower heat duty occurred earlier at $4/MMBtu. This was because of the lower CO₂ production at higher ambient temperatures, making the process unprofitable at a gas price higher than $3/MMBtu unless the heat duty of the stripper and natural gas boiler is steeply decreased. |
| Author | Abreu, Miguel Babu, Athreya Suresh Rochelle, Gary T. Chen, Yee Lee Drewry, Benjamin |
| AuthorAffiliation | Texas Carbon Management Program, McKetta Department of Chemical Engineering |
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| Snippet | A rating model of Piperazine with the Advanced Stripper (PZAS) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance... A rating model of PZAS (Piperazine with the Advanced Stripper) for a 460 MW natural gas combined cycle was developed from vendor-provided equipment performance... |
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| StartPage | 13911 |
| SubjectTerms | Absorption ambient temperature Atmospheric chemistry carbon dioxide chemistry cold electricity costs Environmental pollution equipment performance heat INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY natural gas piperazine Power profitability Separations Solvents specific heat |
| Title | Optimization of Operating Profit for the FEED of the PZAS Process for CO2 Capture on a 460 MW NGCC |
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