Abstract
Based on the rising environmental pollution and finite fossil fuel new storage system must develop to dissipate the primary energy source of renewable energy to the second energy source, like hydrogen. A view into the field of pressure tank technology shows that usually today it is common practice to design a huge cylinder tank. On market, the state of the art high pressure storage systems, type III or type IV, are classified in the Regulation (EC) No 79/2009 [1]. The idea of the new design is to store as much as possible mass of hydrogen in a smaller volume without losing a lot of constructed space. The first idea is to reduce the inner diameter and create new design based on bending pipes. The smaller cross-sectional area of the pipe caused lower tangential and axial stresses with the result of reducing the wall thickness and resulting weight. This modification has a negative influence of the whole structure, because with decreasing diameter the relation between these significant masses also gets worse, as the inside volume of the pipes gets lower. The challenge of drafting a new high pressure storage system is to find a compromise between the optimum diameter for a good amount of inside volume and comparably low mass of the hydrogen storage structure. The comfort for the user, volume and mass of hydrogen for the car depends on the design.
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References
Regulation (EC) no 79/2009 of the European Parliament and of the Council of 14 January 2009 on type-approval of hydrogen-powered motor vehicles, and amending Directive 2007/46/EC
Schlick T (2013) Zukunft der Elektromobilität. auto.mobilFORUM Veritas Gelnhausen, November 2013
Mensen H (2013) Handbuch der Luftfahrt. Springer, New York
Böhm M, Bundeswehr München, Universität der (Hrsg.) (2007) Gesamtentwurf eines ökonomischen und ökologischen Lufttransportsystems unter Ausnutzung von Synergieeekten. Dissertation
Novak P (2006) Ein Beitrag zur Strukturoptimierung dickwandiger Hybrid-Hochdruckspeicher. VDI-Verlag
DIN 2413 (2010) Seamless steel tubes for oil- and water-hydraulic systems—calculation rules for pipes and elbows for dynamic loads
DOE; 4, Revision: targets for onboard hydrogen storage systems for light -duty vehicles. US Department of Energy Office of Energy Efficiency and Renewable Energy and The Freedom CAR and Fuel Partnership, September 2009
Annaratone D (2007) Pressure vessel design. Springer, Berlin
Schürmann H, 2., bearb. und erw. A. (Hrsg.) (2007) Konstruieren mit Faser- Kunststoff-Verbunden. 2. Springer, Berlin
Basan R (2011) Untersuchung der intralaminaren Schubeigenschaften von Faserverbundwerkstoffen mit Epoxidharzmatrix unter Berücksichtigung nichtlinearer Effekte Bundesanstalt für Materialforschung und -prüfung (BAM)
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Duschek, D., Wellnitz, J. (2015). Design of a New Innovative High Pressure Hydrogen System Depending on Multi-layer Section. In: Denbratt, I., Subic, A., Wellnitz, J. (eds) Sustainable Automotive Technologies 2014. Lecture Notes in Mobility. Springer, Cham. https://doi.org/10.1007/978-3-319-17999-5_20
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DOI: https://doi.org/10.1007/978-3-319-17999-5_20
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