Mathematical modeling was used to analyze a number of membrane-catalytic devices with different throughputs and designs and to establish a reasonable quantitative correlation of the calculated parameters and experimental data for hydrogen production and waste-gas composition in order to increase the energy efficiency of the process for producing high-purity hydrogen from natural gas.
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References
G. F. Tereshchenko, N. V. Orekhova, and M. M. Ermilova, “Metal-containing membrane reactors,” Krit. Tekhnol. Membr., No. 1, 4–20 (2007).
A. B. Vandyshev and V. A. Kulikov, “Preparation of specially pure hydrogen at 500–700°C from methane in high-temperature converter-membrane equipment, combined with a CH4 conversion catalyst,” Khim. Neftegaz. Mashinostr., No. 5, 24–27 (2011).
L. L. Murav’ev, A. B. Vandyshev, and V. M. Makarov, “Modeling membrane extraction of hydrogen from the products of steam conversion of hydrocarbons,” Teor. Osn. Khim. Tekhnol., 33, No. 3, 286–291 (1999).
A. B. Vandyshev and V. A. Kulikov, “Comparison of calculated and experimental flow data for a membrane reformer for special-purity hydrogen production from natural gas,” Khim. Neftegaz. Mashinostr., No. 10, 15–20 (2013).
A. B. Vandyshev and V. A. Kulikov, “Analysis of parameters of high-purity hydrogen production from methane in a laboratory-scale membrane reformer with an ultrathin palladium membrane,” Khim. Neftegaz. Mashinostr., No. 4, 21–25 (2015).
F. Gallucci, E. Fernandez, P. Corengia, and M. Annaland, “(Review) Recent advances on membranes and membrane reactors for hydrogen production,” Chem. Eng. Sci., 92, 40–66 (2013).
F. Gallucci, A. Basile, A. Iulianelli, and H. A. Kuipers, “A review on patents for hydrogen production using membrane reactors,” Recent Pat. Chem. Eng., 2, 207–222 (2009).
Y. Shirasaki, T. Tsuneki, Y. Ota, et al., “Development of membrane reformer system for highly efficient hydrogen production from natural gas,” Int. J. Hydrogen Energy, 34, 4482–4487 (2009).
Y. Shirasaki, T. Tsuneki, T. Takahashi, et al., “New concept hydrogen production system based on membrane reformer,” in: Fuel Cell Seminar, Palm Springs, USA (2002), pp. 733–736.
S. Uemiya, “Brief review of steam reforming using a metal membrane reactor,” Top. Catal., 29, 79–84 (2004).
H. Kurokawa, Y. Shirasaki, T. Tsuneki, et al., “Development of highly efficient membrane reformer system for hydrogen production from natural gas,” in: 17th World Hydrogen Energy Conf., June 15–19, 2008, Brisbane, Australia.
G. S. Burkhanov, N. B. Gorina, N. B. Kol’chugina, and N. R. Roshan, “Palladium alloys for hydrogen energy,” Ross. Khim. Zh., 50, No. 4, 36–40 (2006).
H. Yakabe, T. Iseki, H. Kurokawa, et al., “Development of hydrogen production systems with Pd-based alloy membrane,” in: 19th World Hydrogen Energy Conf., June 3–7, 2012, Toronto, Canada.
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Translated from Khimicheskoe i Neftegazovoe Mashinostroenie, No. 1, pp. 34–38, January, 2017.
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Vandyshev, A.B., Kulikov, V.A. Analysis of Parameters and Modes for Producing High-Purity Hydrogen from Natural Gas in Membrane-Catalytic Devices. Chem Petrol Eng 53, 49–55 (2017). https://doi.org/10.1007/s10556-017-0293-y
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DOI: https://doi.org/10.1007/s10556-017-0293-y