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Manuscript ID : JEST-1901-4565 (R2) Visit : 120 Page: 39 - 50

10.22034/jest.2021.42400.4565

Article Type: Original Research

Mass Transfer Modeling For CO2 Removal from Environment with the Aim of Green Biomethanation and Methanogens Growth Optimization

Subject Areas : Air Pollution

Seyed Ali Jafari 1 , Shahriar Osfouri 2 , Reza Azin 3

1 - PhD Sudent, Department of Chemical Engineering, Faculty of Petroleum, Gas, and Petrochemical Engineering, Persian Gulf University, Bushehr, Iran.
2 - Associated professor Department of Chemical Engineering, Faculty of Petroleum, Gas, and Petrochemical Engineering, Persian Gulf University, Bushehr, Iran. *(Corresponding Author)
3 - Associated professor Department of Chemical Engineering, Faculty of Petroleum, Gas, and Petrochemical Engineering, Persian Gulf University, Bushehr, Iran.

Received: 2019-03-06 Accepted : 2019-11-13 Published : 2021-02-19

Keywords: CO2 removal, Mathematical Modeling, Biomethane, Mass Transfer, Hydrogen,

Abstract :

Background and Objective: CO2 concentration, as the main greenhouse gas, is growing in atmosphere and many alternatives have been investigated to deal with it. However, harnessing with the aim of biomethanation seems to be more economic. Method: In this study a mass transfer modeling was conducted for a biomethanation process under a batch strategy aiming at maximizing liquid active volume. The accuracy of modeling results was assessed via comparing with experimental data and kinetic results under zero-dimension study. Then one-dimensional study was conducted in order to investigate biomass and hydrogen concentration profiles within liquid phase of the bioreactor and active volume calculation. Response surface method (RSM) was also served to investigate effect of temperature, pressure and as three main factors on active volume followed by response optimization. Findings: Model accuracy was confirmed by zero-dimension study. One-dimensional study was also revealed that biomass growth dispersion within liquid phase depends on hydrogen profile concentration on condition that both hydrogen and biomass diffusion coefficients were assumed to be equal. Their degree of magnification was 10-9  in standard conditions. RSM showed that the three studied factors significantly affected on bioreactor active volume. Meanwhile, pressure and temperature influenced the most, respectively. Discussion and Conclusion: A batch bioreactor with  and high pressure and temperature met optimal conditions for biomethanation; however, process economy defines operational limitations.  

References:


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_||_

  1.  Leu JY, Lin YH, Chang FL. Conversion of CO2 into CH4 by methane-producing bacterium FJ10 under a pressurized condition. Chemical Engineering Research and Design. 2011;89(9):1879–90.
    2.
  2. US EPA E. Inventory of US greenhouse gas emissions and sinks: 1990–2016. Washington, DC, USA, EPA. 2018.
    3.
  3. Oberthür S, Groen L. Explaining goal achievement in international negotiations: the EU and the Paris Agreement on climate change. Journal of European Public Policy. 2018;25(5):708-27.
    4.
  4. Squalli J. Renewable energy, coal as a baseload power source, and greenhouse gas emissions: Evidence from U.S. state-level data. Energy. 2017;127:479-88.
    5.
  5. Zabranska J, Pokorna D. Bioconversion of carbon dioxide to methane using hydrogen and hydrogenotrophic methanogens. Biotechnol Adv. 2018;36(3):707-20.
    6.
  6. Brooks KP, Hu J, Zhu H, Kee RJ. Methanation of carbon dioxide by hydrogen reduction using the Sabatier process in microchannel reactors. Chemical Engineering Science. 2007;62(4):1161-70.
    7.
  7. Inkeri E, Tynjälä T, Laari A, Hyppänen T. Dynamic one-dimensional model for biological methanation in a stirred tank reactor. Applied Energy. 2018;209:95–107.
    8.
  8. Luo G, Johansson S, Boe K, Xie L, Zhou Q, Angelidaki I. Simultaneous hydrogen utilization and in situ biogas upgrading in an anaerobic reactor. Biotechnol Bioeng. 2012;109(4):1088-94.
    9.
  9. Seifert A, Rittmann S, Herwig C. Analysis of process related factors to increase volumetric productivity and quality of biomethane with Methanothermobacter marburgensis. Applied Energy. 2014;132:155-162.
    10.
  10. Savvas S, Donnelly J, Patterson T, Chong ZS, Esteves SR. Biological methanation of CO2 in a novel biofilm plug-flow reactor: A high rate and low parasitic energy process. Applied Energy. 2017;202:238–47.
    11.
  11. Daglioglu ST, Karabey B, Ozdemir G, Azbar N. CO2 utilization via a novel anaerobic bioprocess configuration with simulated gas mixture and real stack gas samples. Environ Technol. 2017:1-7.
    12.
  12. Diaz I, Perez C, Alfaro N, Fdz-Polanco F. A feasibility study on the bioconversion of CO2 and H2 to biomethane by gas sparging through polymeric membranes. Bioresour Technol. 2015;185:246-53.
    13.
  13. Hayduk W, Laudie H. Prediction of diffusion coefficients for nonelectrolytes in dilute aqueous solutions. AIChE Journal. 1974;20(3):611-5.
    14.
  14. Schmelzer JW, Zanotto ED, Fokin VM. Pressure dependence of viscosity. The Journal of chemical physics. 2005;122(7):074511.
    15.
  15. Fernández-Prini R, Alvarez JL, Harvey AH. Henry’s constants and vapor–liquid distribution constants for gaseous solutes in H 2 O and D 2 O at high temperatures. Journal of Physical and Chemical Reference Data. 2003;32(2):903-16.
    16.
  16. Leonzio G. Process analysis of biological Sabatier reaction for bio-methane production. Chemical Engineering Journal. 2016;290:490-8.
    17.

 

 

 

 

 

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