13 research outputs found
Analysis of Process Configurations for CO2 Capture by Precipitating Amino Acid Solvents
Precipitating amino acid solvents are an alternative to conventional amine scrubbing for CO2 capture from flue gas. Process operation with these solvents leads to the formation of precipitates during absorption that need to be re-dissolved prior to desorption of CO2. The process configuration is crucial for the successful application of these solvents. Different process configurations have been analyzed in this work, including a full analysis of the baseline operating conditions (based on potassium taurate), the addition of lean vapor compression, multiple absorber feeds, and the use of different amino acids as alternative solvents to the baseline based on potassium taurate. The analysis is carried out with an equilibrium model of the process that approximates the thermodynamics of the solvents considered. The results show that the precipitating amino acid solvents can reduce the reboiler duty needed to regenerate the solvent with respect to a conventional MEA process. However, this reduction is accompanied by an expenditure in lower grade energy needed to dissolve the precipitates. To successfully implement these processes into power plants, an internal recycle of the rich stream is necessary. This configuration, known as DECAB Plus, can lower the overall energy use of the capture process, which includes the energy needed to regenerate the solvent, the energy needed to dissolve the precipitates, and the energy needed to compress the CO2 to 110 bar. With respect to the energy efficiency, the DECAB Plus with lean vapor compression configuration is the best configuration based on potassium taurate, which reduces the reboiler duty for regeneration by 45% with respect to conventional MEA. Retrofitting this process into a coal fired power plant will result in overall energy savings of 15% with respect to the conventional MEA process, including compression of the CO2 stream to 110 bar. Potassium alanate was found to reduce the energy use with respect to potassium taurate under similar process configurations. Therefore, the investigation of potassium alanate in a DECAB Plus configuration is highly recommended, since it can reduce the energy requirements of the best process configuration based on potassium taurat
Online monitoring of the solvent and absorbed acid gas concentration in a CO2 capture process using monoethanolamine
A method has been developed for online liquid analysis of the amine and absorbed CO2 concentrations in a postcombustion capture process using monoethanolamine (MEA) as a solvent. Online monitoring of the dynamic behavior of these parameters is important in process control and is currently achieved only using Fourier transform infrared spectroscopy. The developed method is based on cheap and easy measurable quantities. Inverse least-squares models were built at two temperature levels, based on a set of 29 calibration samples with different MEA and CO2 concentrations. Density, conductivity, refractive index, and sonic speed measurements were used as input data. The developed model has been validated during continuous operation of a CO2 capture pilot miniplant. Concentrations of MEA and CO2 in the liquid phase were predicted with an accuracy of 0.53 and 0.31 wt %, with MEA and CO2 concentrations ranging from 19.5 to 27.7 wt % and from 1.51 to 5.74 wt %, respectively. Process dynamics, like step changes in the CO2 flue gas concentration, were covered accurately, as well. The model showed good robustness to changes in temperature. Combining density, conductivity, refractive index, and sonic speed measurements with a multivariate chemometric method allows the real-time and accurate monitoring of the acid gas and MEA concentrations in CO2 absorption processes.Scopu
Conceptual design of a novel CO2 capture process based on precipitating amino acid solvents
Amino acid salt based solvents can be used for CO2 removal from flue gas in a conventional absorption–thermal desorption process. Recently, new process concepts have been developed based on the precipitation of the amino acid zwitterion species during the absorption of CO2. In this work, a new concept is introduced which requires the precipitation of the pure amino acid species and the partial recycle of the remaining supernatant to the absorption column. This induces a shift in the pH of the rich solution treated in the stripper column that has substantial energy benefits during CO2 desorption. To describe and evaluate this concept, this work provides the conceptual design of a new process (DECAB Plus) based on a 4 M aqueous solution of potassium taurate. The design is supported by experimental data such as amino acid speciation, vapor–liquid equilibria of CO2 on potassium taurate solutions, and solid–liquid partition. The same conceptual design method has been used to evaluate a baseline case based on 5 M MEA. After thorough evaluation of the significant variables, the new DECAB Plus process can lower the specific reboiler energy for solvent regeneration by 35% compared to the MEA baseline. The specific reboiler energy is reduced from 3.7 GJ/tCO2, which corresponds to the MEA baseline, to 2.4 GJ/tCO2, which corresponds to the DECAB Plus process described in this work, excluding the low-grade energy required to redissolve the precipitates formed during absorption. Although this low-grade energy will eventually reduce the overall energy savings, the evaluation of DECAB Plus has indicated the potential of this concept for postcombustion CO2 captur
Online Monitoring of the Solvent and Absorbed Acid Gas Concentration in a CO<sub>2</sub> Capture Process Using Monoethanolamine
A method
has been developed for online liquid analysis of the amine
and absorbed CO<sub>2</sub> concentrations in a postcombustion capture
process using monoethanolamine (MEA) as a solvent. Online monitoring
of the dynamic behavior of these parameters is important in process
control and is currently achieved only using Fourier transform infrared
spectroscopy. The developed method is based on cheap and easy measurable
quantities. Inverse least-squares models were built at two temperature
levels, based on a set of 29 calibration samples with different MEA
and CO<sub>2</sub> concentrations. Density, conductivity, refractive
index, and sonic speed measurements were used as input data. The developed
model has been validated during continuous operation of a CO<sub>2</sub> capture pilot miniplant. Concentrations of MEA and CO<sub>2</sub> in the liquid phase were predicted with an accuracy of 0.53 and
0.31 wt %, with MEA and CO<sub>2</sub> concentrations ranging from
19.5 to 27.7 wt % and from 1.51 to 5.74 wt %, respectively. Process
dynamics, like step changes in the CO<sub>2</sub> flue gas concentration,
were covered accurately, as well. The model showed good robustness
to changes in temperature. Combining density, conductivity, refractive
index, and sonic speed measurements with a multivariate chemometric
method allows the real-time and accurate monitoring of the acid gas
and MEA concentrations in CO<sub>2</sub> absorption processes
In-Line Monitoring of the CO<sub>2</sub>, MDEA, and PZ Concentrations in the Liquid Phase during High Pressure CO<sub>2</sub> Absorption
This
article provides results of the <i>in situ</i> monitoring
of carbon dioxide (CO<sub>2</sub>) removal under high pressure. An
aqueous solution of methyldiethanolamine (MDEA) promoted by piperazine
(PZ) for absorption rate acceleration was used. This system is promising
for natural gas purification. A predictive statistical model was built
using the chemometrics method and measurements of density, pH, conductivity,
sound velocity, refractive index, and Near Infra-Red (NIR) spectroscopy.
The CO<sub>2</sub> capture rate ranged from 60% up to 96% at pressures
in the absorber column ranging between 15 and 20 bar. The liquid stream
composition was monitored at the low pressure part of a pileline at
a location before a compressor stage. The concentrations of MDEA,
PZ, and CO<sub>2</sub> were predicted in-line using different sets
of the measurement devices during 3 days of the measurement campaign.
The developed approach allowed for prediction of the concentrations
with accuracies of 0.7% for MDEA, 0.4% for PZ, and 2.5% for CO<sub>2</sub>
Analysis of Process Configurations for CO<sub>2</sub> Capture by Precipitating Amino Acid Solvents
Precipitating
amino acid solvents are an alternative to conventional
amine scrubbing for CO<sub>2</sub> capture from flue gas. Process
operation with these solvents leads to the formation of precipitates
during absorption that need to be re-dissolved prior to desorption
of CO<sub>2</sub>. The process configuration is crucial for the successful
application of these solvents. Different process configurations have
been analyzed in this work, including a full analysis of the baseline
operating conditions (based on potassium taurate), the addition of
lean vapor compression, multiple absorber feeds, and the use of different
amino acids as alternative solvents to the baseline based on potassium
taurate. The analysis is carried out with an equilibrium model of
the process that approximates the thermodynamics of the solvents considered.
The results show that the precipitating amino acid solvents can reduce
the reboiler duty needed to regenerate the solvent with respect to
a conventional MEA process. However, this reduction is accompanied
by an expenditure in lower grade energy needed to dissolve the precipitates.
To successfully implement these processes into power plants, an internal
recycle of the rich stream is necessary. This configuration, known
as DECAB Plus, can lower the overall energy use of the capture process,
which includes the energy needed to regenerate the solvent, the energy
needed to dissolve the precipitates, and the energy needed to compress
the CO<sub>2</sub> to 110 bar. With respect to the energy efficiency,
the DECAB Plus with lean vapor compression configuration is the best
configuration based on potassium taurate, which reduces the reboiler
duty for regeneration by 45% with respect to conventional MEA. Retrofitting
this process into a coal fired power plant will result in overall
energy savings of 15% with respect to the conventional MEA process,
including compression of the CO<sub>2</sub> stream to 110 bar. Potassium
alanate was found to reduce the energy use with respect to potassium
taurate under similar process configurations. Therefore, the investigation
of potassium alanate in a DECAB Plus configuration is highly recommended,
since it can reduce the energy requirements of the best process configuration
based on potassium taurate
Real-Time Process Monitoring of CO<sub>2</sub> Capture by Aqueous AMP-PZ Using Chemometrics: Pilot Plant Demonstration
A combination
of analytical instrumentation and multivariate statistics
is widely applied to improve in-line process monitoring. Currently,
postcombustion CO<sub>2</sub> capture (PCC) technology often involves
the use of multiamine based chemical reagents for carbon dioxide removal
from flue gas. The CO<sub>2</sub> capture efficiency and overall process
performance may be improved by introduction of the chemometrics analytical
methods for flexible and reliable process monitoring. In this study,
six variables were measured (conductivity, pH, density, speed of sound,
refractive index, and near-infrared absorbance spectra). A compact
data-collecting chemometric setup was constructed and installed at
an industrial pilot plant for real-case testing. This setup was applied
to the characterization of CO<sub>2</sub> absorption into aqueous
2-amino-2-methyl-1-propanol (AMP) activated by piperazine (PZ) as
the absorption agent. A partial least-squares (PLS) regression model
was calibrated and validated based on the measurements conducted in
the laboratory environment. The developed approach was applied to
predict the concentrations of AMP, PZ, and CO<sub>2</sub> with accuracies
of ±2.1%, ± 3.5%, and ±4.3%, respectively. The model
was constructed to include the temperature dependency in order to
make it insensitive to operational temperature fluctuations during
a CO<sub>2</sub> capture process. The setup and model have been tested
for almost 850 hours of in-line measurements at a postcombustion CO<sub>2</sub> capture pilot plant. To provide validation of the chemometrics
approach, an off-line analysis of the samples has been conducted.
The results of the validation technique benchmarking appear to be
consistent with values predicted in-line, with average deviations
of ±1.8%, ± 1.3%, and ±3.9% for the concentrations
of AMP, PZ, and CO<sub>2</sub>, respectively
Conceptual Design of a Novel CO<sub>2</sub> Capture Process Based on Precipitating Amino Acid Solvents
Amino acid salt based solvents can
be used for CO<sub>2</sub> removal
from flue gas in a conventional absorption–thermal desorption
process. Recently, new process concepts have been developed based
on the precipitation of the amino acid zwitterion species during the
absorption of CO<sub>2</sub>. In this work, a new concept is introduced
which requires the precipitation of the pure amino acid species and
the partial recycle of the remaining supernatant to the absorption
column. This induces a shift in the pH of the rich solution treated
in the stripper column that has substantial energy benefits during
CO<sub>2</sub> desorption. To describe and evaluate this concept,
this work provides the conceptual design of a new process (DECAB Plus)
based on a 4 M aqueous solution of potassium taurate. The design is
supported by experimental data such as amino acid speciation, vapor–liquid
equilibria of CO<sub>2</sub> on potassium taurate solutions, and solid–liquid
partition. The same conceptual design method has been used to evaluate
a baseline case based on 5 M MEA. After thorough evaluation of the
significant variables, the new DECAB Plus process can lower the specific
reboiler energy for solvent regeneration by 35% compared to the MEA
baseline. The specific reboiler energy is reduced from 3.7 GJ/tCO<sub>2</sub>, which corresponds to the MEA baseline, to 2.4 GJ/tCO<sub>2</sub>, which corresponds to the DECAB Plus process described in
this work, excluding the low-grade energy required to redissolve the
precipitates formed during absorption. Although this low-grade energy
will eventually reduce the overall energy savings, the evaluation
of DECAB Plus has indicated the potential of this concept for postcombustion
CO<sub>2</sub> capture