Modeling and Optimization of Membrane Reactors for Carbon Capture In IGCC Units

Tuesday, October 18, 2011: 1:45 PM
200 E (Minneapolis Convention Center)
Fernando V. Lima1, Prodromos Daoutidis1, Michael Tsapatsis1 and John J. Marano2, (1)Department of Chemical Engineering and Materials Science, University of Minnesota, Minneapolis, MN, (2)JM Energy Consulting, Inc., Gibsonia, PA

According to DOE projections, carbon dioxide (CO2) emissions from the combustion of fossil fuels will exceed six billion metric tons by 2035. About one-third of these emissions originate from coal-fired electricity generation [1].  These emissions will need to be mitigated in order to reduce the impact of projected climate change within this century [2]. Thus, there is a need to develop new technologies for economical production of electricity from coal that minimize the release of CO2 to the atmosphere. Integrated Gasification Combined Cycle (IGCC) power plants are a promising technology that can achieve higher efficiencies than conventional pulverized coal (PC)-fired plants. IGCC units also enable CO2 capture with lower penalties in energy efficiency and cost of electricity than their PC counterparts [3]. In this presentation, we investigate the alternative of pre-combustion capture of CO2 from IGCC plants using membrane reactors equipped with H2-selective molecular sieve (zeolite) membranes for the water gas shift (WGS) reaction.

A challenge with using H2-selective membranes in the WGS section of coal-based gasification plants is their stability under high pressure and temperature conditions, and in the presence of steam and possibly other traces components such as hydrogen sulfide (H2S). Typical membrane materials used or proposed for H2 separations as well as the issues associated with each group of materials under WGS conditions [4] are: (i) metals (typically Pd-based): high cost, stability in the presence of contaminants (H2S) and H2 embrittlement; (ii) polymers: thermal degradation; (iii) amorphous silica: hydrothermal stability. Zeolite-based, molecular sieve membranes are one promising alternative for this application, as they are hydrothermally stable and have potential for high selectivity and flux [5].

The objective of this work is to develop a membrane reactor model for the WGS reaction using zeolite membranes. The developed model will be used for stand-alone simulation and optimization studies, and will ultimately be integrated into an IGCC system model. These studies aim to determine the membrane characteristics necessary to achieve the U.S. DOE R&D goal of 90% CO2 capture [6] and to obtain desired H2 recovery and CO conversion values. The desired targets should be reached for an optimal membrane use and without violating constraints in the reactor outlet streams, such as the retentate stream (rich in CO2) for capture and sequestration and the permeate stream (rich in H2) for power generation.

Regarding the modeling task, we have developed a one-dimensional and isothermal shell and tube membrane reactor model for the WGS reaction. The model assumes the catalyst is packed in the tube side, a thin membrane layer is placed on the interior surface of the tube wall and the sweep gas flows in the shell side.  This reactor model was simulated considering co-current and counter-current flow configurations to obtain steady-state compositions for primary species (CO, H2O, CO2, H2 and N2) present in the retentate and permeate streams. Several case studies have been performed assuming different membrane characteristics (permeance and selectivity). For each case study, we calculated the values of the membrane reactor parameters, such as CO conversion, H2 recovery/productivity and CO2 capture; and computed stream purities, such as the CO2 purity in the retentate and H2 purity in the permeate. Target values for these parameters as well as constraints for the reactor streams were defined based on data reported by the DOE [7]. The simulation set up considers WGS reactor operating conditions that are taken from the literature and are consistent with IGCC units. Simulation results showed good agreement with published simulation data [8] and a better performance for the counter-current configuration when compared to the co-current mode.

Regarding the optimization task, we formulated and solved a novel optimization problem using the developed membrane reactor model to guide the selection of the optimal reactor design among typical scenarios of operation, including: (i) pre-shift, membrane separator, WGS reactor; (ii) pre-shift, WGS membrane reactor; (iii) WGS reactor, membrane separator; (iv) stand-alone WGS membrane reactor. To address all of these design alternatives in one formulation, the decision variables considered in the problem were specified as the lengths associated with the reaction and permeation zones. The problem was solved with the objectives of maximizing the CO conversion and H2 recovery, while minimizing the cost of membrane used as a function of its surface area required. This problem was also subjected to the target specifications in the membrane reactor parameters and constraints in the retentate and permeate streams that were mentioned above. Optimization results indicated as optimal solution the reactor design with a pre-shift followed by a WGS membrane reactor and potential savings in membrane material when compared to the original membrane reactor design.

References

[1] DOE/EIA. Annual Energy Outlook, 2010.

[2] Susan Solomon, Dahe Qin, Martin Manning, Melinda Marquis, Kristen Averyt, Melinda M. B. Tignor, Henry LeRoy Miller Jr., and Zhenlin Chen. Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, New York, NY, 2007.

[3] Mark C. Woods, Pamela J. Capicotto, John L. Haslbeck, Norma J. Kuehn, Michael Matuszewski, Lora L. Pinkerton, Michael D. Rutkowski, Ronald L. Schoff, and Vladimir Vaysman. Cost and performance baseline for fossil energy plants. Volume 1: Bituminous coal and natural gas to electricity final report. Technical Report Revision 1, DOE/NETL-2007/1281, August 2007.

[4] Nathan W. Ockwig and Tina M. Nenoff. Membranes for hydrogen separation. Chem. Rev., 107:4078-4110, October 2007.

[5] Jungkyu Choi and Michael Tsapatsis. MCM-22/Silica selective flake nanocomposite membranes for hydrogen separations. J. Am. Chem. Soc., 132(2):448-449, January 2010.

[6] John J. Marano and Jared P. Ciferno. Integration of gas separation membranes with IGCC - Identifying the right membrane for the right job. Energy Procedia, 1:361-368, February 2009.

[7] John J. Marano. Integration of H2 separation membranes with CO2 capture & compression. Report to DOE, 2010.

[8] Panagiotis Boutikos and Vladimiros Nikolakis. A simulation study of the effect of operating and design parameters on the performance of a water gas shift membrane reactor. J. Membr. Sci., 350:378-386, March 2010.


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