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Advantages of integration with industry for electrolytic hydrogen production

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  • Saxe, Maria
  • Alvfors, Per

Abstract

This paper evaluates possible synergies with industry, such as heat and oxygen recovery from the hydrogen production. The hydrogen production technology used in this paper is electrolysis and the calculations include the cost and energy savings for integrated hydrogen production. Electrolysis with heat recovery leads to both cost reduction and higher total energy efficiencies of the hydrogen production. Today about 15–30% of the energy supplied for the production is lost and most of it can be recovered as heat. Utilization of the oxygen produced in electrolysis gives further advantages. The integration potential has been evaluated for a pulp and paper industry and the Swedish energy system, focusing on hydrogen for the transportation sector. The calculated example shows that the use of the by-product oxygen and heat greatly affects the possibility to sell hydrogen produced from electrolysis in Sweden. Most of the energy losses are recovered in the example; even gains in energy for not having to produce oxygen with cryogenic air separation are shown. When considering cost, the oxygen income is the most beneficial but when considering energy efficiency, the heat recovery stands for the greater part.

Suggested Citation

  • Saxe, Maria & Alvfors, Per, 2007. "Advantages of integration with industry for electrolytic hydrogen production," Energy, Elsevier, vol. 32(1), pages 42-50.
    • Handle: RePEc:eee:energy:v:32:y:2007:i:1:p:42-50
    DOI: 10.1016/j.energy.2006.01.021
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    References listed on IDEAS

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    1. Kato, Takeyoshi & Kubota, Mitsuhiro & Kobayashi, Noriyuki & Suzuoki, Yasuo, 2005. "Effective utilization of by-product oxygen from electrolysis hydrogen production," Energy, Elsevier, vol. 30(14), pages 2580-2595.
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    Cited by:

    1. Rahimpour, M.R. & Mirvakili, A. & Paymooni, K., 2011. "A novel water perm-selective membrane dual-type reactor concept for Fischer–Tropsch synthesis of GTL (gas to liquid) technology," Energy, Elsevier, vol. 36(2), pages 1223-1235.
    2. Olateju, Babatunde & Kumar, Amit, 2011. "Hydrogen production from wind energy in Western Canada for upgrading bitumen from oil sands," Energy, Elsevier, vol. 36(11), pages 6326-6339.
    3. Damien Guilbert & Gianpaolo Vitale, 2021. "Hydrogen as a Clean and Sustainable Energy Vector for Global Transition from Fossil-Based to Zero-Carbon," Clean Technol., MDPI, vol. 3(4), pages 1-29, December.
    4. Lindfeldt, Erik G. & Saxe, Maria & Magnusson, Mimmi & Mohseni, Farzad, 2010. "Strategies for a road transport system based on renewable resources - The case of an import-independent Sweden in 2025," Applied Energy, Elsevier, vol. 87(6), pages 1836-1845, June.
    5. Santos, D.M.F. & Šljukić, B. & Sequeira, C.A.C. & Macciò, D. & Saccone, A. & Figueiredo, J.L., 2013. "Electrocatalytic approach for the efficiency increase of electrolytic hydrogen production: Proof-of-concept using platinum--dysprosium alloys," Energy, Elsevier, vol. 50(C), pages 486-492.
    6. Nordin, Nur Dalilah & Rahman, Hasimah Abdul, 2019. "Comparison of optimum design, sizing, and economic analysis of standalone photovoltaic/battery without and with hydrogen production systems," Renewable Energy, Elsevier, vol. 141(C), pages 107-123.
    7. Mohseni, Farzad & Görling, Martin & Alvfors, Per, 2013. "The competitiveness of synthetic natural gas as a propellant in the Swedish fuel market," Energy Policy, Elsevier, vol. 52(C), pages 810-818.
    8. Klöckner, Kai & Letmathe, Peter, 2020. "Is the coherence of coal phase-out and electrolytic hydrogen production the golden path to effective decarbonisation?," Applied Energy, Elsevier, vol. 279(C).

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