Disosiasi H2S dalam gas alam pada temperatur ruang menggunakan katalisator MgO: pengaruh jumlah katalis dan laju alir massa

Abstract

The presence of H₂S in natural gas is very detrimental to ammonia industry because it can poison and deactivate steam reforming catalysts. In the ammonia plant Pusri-IB PT. Pusri Palembang, H₂S was separated in the Desulfurizer Unit (201-D) by adsorption using ZnO adsorbent at low temperature (28 ° C). Unfortunately, in this process the ZnO adsorbent cannot be regenerated so that within one year the ZnO adsorbent will be saturated with sulfur. The alternative process of H₂S separation is to dissociate H₂S into its constituent elements (hydrogen and sulfur) with catalytic process. The magnesium oxide catalyst was chosen because magnesium oxide is a metal oxide compound widely known in the catalysis process and has two active sites. The highest H₂S conversion that can be achieved by MgO catalyst is 92.29%. Unlike ZnO, MgO does not absorb H₂S, but catalyzes the dissociation of H₂S into hydrogen and solid sulfur without being changed consumed by the reaction itself so that the MgO catalyst has a longer life time than the ZnO adsorbent.

References

1. Calatayud, M., Markovits, A., Menetrey, M., Mguig, B., and Minot, C., 2003, Adsorption on perfect and reduced surfaces of metal oxide, Catal. Today, 85, 125–143.
2. Elkhalifa, E., and Frederich, H., 2014, Magnesium oxide as a catalyst for the dehydrogenation of n-octane, Arabian J. Chem., 11, 1154-1159.
3. Fogler, H.S., 1992, Elements of Chemical Reaction Engineering, Toronto Prentice-Hall International Inc., New Jersey, United States
4. Guldal, N., Figen, H., and Baykara, S., 2015, New catalyst for hydrogen production from H2S: preliminary results, Int. J. Hydrogen Energy, 40, 7452 - 7458.
5. Hagen, J., 2006, Industrial Catalysis: A Practical Approach 2nd Ed., Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim, Germany.
6. Jalama, K., 2015, Effect of space velocity on Fischer-Tropsch reaction over Co/TiO2 catalyst, Proceedings of the World Congress on Engineering and Computer Science 2015, Vol II, 21-23.
7. Karan, K., Mehrotra, A., and Behie, L., 1999,. On reaction kinetics of the thermal decomposition of hydrogen sulfide, AIChE Journal, 45 (2), 383-389.
8. Laosiripojana, N., Rajesh, S., Singhto, W., Palikanon, T., and Pengyong, S., 2004, Effect of H2S, CO2, and O2 on catalytic methane steam reforming over Ni catalyst on CeO2 and Al2O3 support, The Joint International Conference on “Sustainable Energy and Environment (SEE)”
9. Nwosu, C., 2012, An electronegativity approach to catalytic performance, Journal of Technical Science and Technologies, 1 (2), 25-28
10. PT Pupuk Sriwidjaya, 1995, Process Design Package for 1350 mtpd Ammonia Unit, The M.W. Kellog Company
11. Starstev, A., Kruglyakova, O., Chesalov, Y., Ruzankin, S., Kravtsov, E., Larina, T., and Paukshtis, E., 2013, Low temperature catalytic decomposition of hydrogen sulfide into hydrogen and diatomic gaseous sulfur, Top. Catal., 56, 969-980.
12. Wentao, X., Luo, M., Peng, R., Xiang, M., Hu, X., Lan, L., and Zhou, J., 2017, Highly effective microwave catalytic direct decomposition of H2S and S over MeS-based (Me = Ni, Co) microwave catalysts, Energy Convers. Manage., 149, 219-227.
13. Zaman, J., and Chakma, A., 1995, Production of hydrogen and sulfur from hydrogen sulfide, Fuel Process. Technol., 41, 159-198.