The future of the hydrogen economy : bright or bleak?

• Autorzy: Bossel U. , Eliasson B. , Taylor G.
• Języki publikacji: EN

Abstrakty

EN

In the past, many have considered the production and use of hydrogen, assuming that it is just another gaseous fuel and can be handled much like natural gas in todays energy economy. With this study we present an analysis of the energy required to operate an elemental hydrogen economy, with particular reference to rond transport. High-grade electricity from renewable or nuclear sources is needed not only to generate hydrogen, hut also for all the other essential stages. However, because of the molecular structure of hydrogen, the infrastructure is much more energy-intensive than in an oil and natural gas economy. In a "Hydrogen Economy" the hydrogen like any other commercial product, is subject to several stages between production and use. Hydrogen has to be packaged by compression or liquefaction. transported by surface vehicles or pipelines, stored, and transferred to the end user. Whether generated by electrolysis or by chemistry, and even produced locally at filling stations, the gaseous or liquid hydrogen has to undergo these market processes before it can be used by the customer. Hydrogen can also be derived chemically at relatively Iow cost from natural gas or other hydrocarbons. However as there are no energetic or environmental advantages, we do not consider this option. In this study, the energy consumed by each stage is related to the true energy content - the higher heating value (HHV) - of the delivered hydrogen. The analysis reveals that much more energy is needed to operate a hydrogen economy than is required for fossil energy supply and distribution today. In fact, the input of electrical energy to make, package, transport, store and transfer hydrogen may easily exceed the hydrogen energy delivered to the end user - implying an well-totank efficiency of less than 50 per cent. However, precious energy can be saved by packaging hydrogen chemically in a synthetic liąuid hydrocarbon like in ethanol or ethanol. To de-couple energy use front global warming, the use of "geocarbons" from fossil sources should be avoided. However, carbon atoms from biomass, organic waste materials or recycled carbon dioxide could become the carriers for hydrogen atoms. Furthermore, energy intensive electrolysis may be partially replaced by the less energy intensive chemical transformation of water and carbon to natural and synthetic hydrocarbons, including bio-methanol and bio-ethanol. Hence, the closed natural hydrogen (water) cycle and the closed natural carbon (CO2) cycle may be used to produce synthetic hydrocarbons for a post-fossil fuel energy economy. As long as the carbon comes from the biosphere ("bio-carbon"), the synthetic hydrocarbon economy would be far better than the elemental hydrogen economy - both energetically and environmentally.

Słowa kluczowe

EN

alternative fuels; hydrogen; hydrogen economy

• Wydawca: Łukasiewicz Research Network - Institute of Aviation ; European Science Society of Powertrain and Transport KONES Poland ; Wydawnictwo Instytutu Technicznego Wojsk Lotniczych
• Czasopismo: Journal of KONES
• Rocznik: 2004
• Tom: Vol. 11, No. 1-2
• Strony: 87--111
• Opis fizyczny: Bibliogr. 24 poz., rys.

Twórcy

autor

Bossel U.

• European Fue Cell Forum Morgenacherstrasse 2F CH-5452 Oberrohrdorf/ Switzerl tel: +41-56-496-729

autor

Eliasson B.

• ABB Switzerland Ltd. Corporate Research CH-5405 Baden-Duttwil / Switzerland

autor

Taylor G.

• G T Systems 19 The Vale, Stock Ingatestone CM4 9PW I United Kingdom

Bibliografia

• [1] "The Future of the Hydrogen Economy: Bright or Bleak?", Baldur Eliasson and Ulf Bossel, Proceedings, THE FUEL CELL WORLD, Lucerne / Switzerland, July 2002.
• [2] „Handbook of Chemistry and Physics”, recent editions.
• [3] G. H. Aylward, T. J. V. Findlay, „Datensammlung Chemie in SI-Einheiten", 3. Auflage (German Edition), WILEY-VCH. 1999.
• [4] „Synthetic Fuels”, R. F. Probstein and R. E. Hicks, Mc-Graw Hill, 1982.
• [5] Properties of Fuels. http://www.afdc.doe.gov/pdfs/fueltable.pdf.
• [6] H. Audus, Olav Kaarstad and Mark Kowal, ,Decarbonisation of Fossil Fuels: Hydrogen as an Energy Carrier". C02 Conference, Boston/Cambridge 1997, published in Energy Conversion Management, Vol. 38, Suppl., pp. 431-436.
• [7] E. Schmidt, „Technische Thermodynamik". 11th Edition, Vol.l, p. 287 (1975).
• [8] Burckhardt Compression AG, Winterthur / Switzerland (private communication).
• [9] „Die Schlüsselrolle der Kryotechnik in der Wasserstoff-Energiewirtschaft" H. Quack, TU Dresden / Germany. www .tu-dresden.de/mwiem/kkt/mitarbeiter/lib/wasserstoff/wassertech.html
• [10] „Flüssigwasserstoff für Europa - die Linde-Anlage in Ingolstadt", Rein hard Gross, Wolfgang Otto, Adolf Patzelt and Manfred Wanner, Berichte aus Technik und Wissenschaften 71 ( 1994).
• [11] Linde Kryotechnik AG. www.linde-kryotechnik.ch/deutscheversion/anlagen/linde_kryo_ht.htm
• [12] „Study of Large Hydrogen Liquefaction Process”, H. Matsuda and M. Nagami, Nippon Sanso Corp., Kanagawa / Japan ( 1997).http://www .enaa.or.jp/WE-NET/ron bun/ 1997 /e5/sanso 1997.html
• [ 13] Linde Kryotechnik AG, Pfungen I Switzerland (private communication).
• [14] „Hydrogen as an Energy Carrier”, C. I. Winter and J. Nitsch, Editors, Springer Verlag, 1988.
• [15] Product specifications, HERA Hydrogen Storage Systems GmbH, Hofener Strasse 45, DE-90431 Nürnberg / Germany.
• [16] Lawrence D. Burns et al., „Vehicle of Change”, Scientific American, p. 47, (October 2002).
• [17] Ullmann's Encyclopedia of Industrial Chemistry, VCH Verlagsgesellschaft, Weinheim / Germany (1996).
• [18] Messer-Griesheim AG, Krefeld / Germany (hydrogen gas, private communication).
• [19] Esso (Schweiz) AG, Zurich / Switzerland (gasoline and diesel, private communication).
• [20] Jani GmbH & Co. KG, Seevetal / Germany (propane, private communication).
• [21] Hoyer GmbH, Koln I Germany (liquid natural gas, private communication).
• [23] Swissgas Schweiz AG, Zurich, Switzerland (private communication).
• [22] VDI „Wärmeatlas”', VDI Düsseldorf, Germany 1977.
• [24] „Bioenergy: An Overview”, U.S. Department of Energy.www.eere.energy.gov/consumerinfo/refbriefs/nb2.html .