Hostname: page-component-848d4c4894-xm8r8 Total loading time: 0 Render date: 2024-07-03T15:30:54.150Z Has data issue: false hasContentIssue false
  • English
  • Français

Recent Advances in Solid Hydrogen Storage Systems

Published online by Cambridge University Press:  26 February 2011

B.S. Chao ,
R.C. Young ,
V. Myasnikov ,
Y. Li ,
B. Huang ,
F. Gingl ,
P.D. Ferro ,
V. Sobolev  and
S.R. Ovshinsky
B.S. Chao
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
R.C. Young
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
V. Myasnikov
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
Y. Li
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
B. Huang
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
F. Gingl
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
P.D. Ferro
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
V. Sobolev
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
S.R. Ovshinsky
Affiliation:
Texaco Ovonic Hydrogen Systems, LLC, 2983 Waterview Dr., Rochester Hills, MI 48309
Get access

Abstract

Hydrogen energy offers great promise as an energy alternative. Hydrogen technologies can reduce and eliminate the release of carbon dioxide from fossil-fuel combustion, the main cause of global warming. One of the main challenges is hydrogen storage. Storing hydrogen in the solid-state hydride form holds a volumetric advantage over compressed and liquid hydrogen states. Solid hydrogen storage systems also have features of low-pressure operation, compactness, safety, tailorable delivery pressure, excellent absorption /desorption kinetics, modular design for easy scalability, and long cycle life.

In this paper, solid hydrogen storage systems (such as portable power canisters, lightweight fiber wrapped vessels, and aluminum tubular vessels, developed by Texaco Ovonic Hydrogen Systems LLC) will be discussed. A system of four canisters each storing approximately 80 grams of reversible hydrogen is shown to run a 1 kW PEM fuel cell for more than 247 minutes at full power. Canisters show no plastic deformation after more than 500 charge/discharge cycles. The measured strain on canister surfaces indicates that DOT stress limits are not exceeded. The canisters are in the early commercialization stage for uninterrupted power supply (UPS) and auxiliary power unit (APU) applications.

A lightweight fiber-wrapped vessel engineered with metal hydride and internal heat exchanger is being developed for onboard applications. At the system level, the vessel has a volumetric energy density of 50 grams of hydrogen per liter and a gravimetric density of 1.6 wt.%. The vessel is capable of storing 3 kg of hydrogen with a fast refueling capability. Ninety percent of the storable hydrogen can be refueled in 10 minutes at 1500 psig. The vessel can easily release the hydrogen at a rate of 350 slpm at 70°C.

Aluminum tubular vessels are being designed and tested for bulk storage and infrastructure applications including stationary power, hydrogen shipment and hydrogen service stations. The tubular vessel dimensions may be designed for specific applications. For example, a tubular vessel 6 inches in diameter and 62 inches in length can store up to 1 kg of hydrogen.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 801: Symposium BB – Materials and Technologies for a Hydrogen Economy , 2003 , BB1.4
Copyright
Copyright © Materials Research Society 2004

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1. Phillips, Owen, The Last Chance Energy Book, The Johns Hopkins University Press (1979).Google Scholar
2. Gregory, D.P., Electrochemistry of Cleaner Environments, Chapter 8, Plenum Press, editor Bockris, J.O'M. (1972).Google Scholar
3. Jones, L.W., Science 174, 367370 (1971).Google Scholar
4. Bockris, J.O'M., Science 176, 1323 (1972).Google Scholar
5. Hartley, R.M. (Ed.), Hydrogen Progress, 2nd Quarter 1977 (Billings Energy Corp., Provo. UT).Google Scholar
6. Ergenics, Inc., 247 Margaret King Avenue, Ringwood N.J. 07456, USA.Google Scholar
7. Hydrogen Consultants, Inc., (now Hydrogen Components, Inc.) 12420 N. Dumont Way, Littleton CO 80125 USA.Google Scholar
8. Mccue, J.C., J. Less-Common Met. 74, 333 (1980).Google Scholar
9. HWT Gesellschaft fur Hydrid – und Wasserstofftechnik mbH, Postfach 100827, 4330 Mulheim a.d. Ruhr, FRG.Google Scholar
10. Suzuki Shokan Co., 3–1 Kojimachi, Chiyoda–ku, Tokyo 102, Japan.Google Scholar
11. Strickland, G., Reilly, J.J., Wiswall, R.H. Jr, Proc. Of the Hydrogen Economy Miami Energy (THEME) Conference (Univ. of Miami, Coral Gables, FL 1974) pp. S49–S4–21.Google Scholar
12. Burger, J.M., Lewis, P.A., Isler, R.J., Salzano, F.J., King, J.M. Jr, Porc. 9th Intersociety Energy conversion Engineering Conf. (ASME, New York 1974) pp 428434.Google Scholar
13. Baker, N., Huston, L., Lynch, F., Olavson, L., Sandrock, G., Final Phase I Report for U.S. Bureau of Mines Contract H0202034 (Eimco Mining Machinery International, Salt Lake City, UT 1981), pp. 127129.Google Scholar
14. See for example, HYDROGEN POWER, by Williams, L.O., Pergamom Press Inc. New York, 1980.Google Scholar
Turillon, P.P., Proceedings of the 4th World Hydrogen Energy Conference, CA, USA, p. 1289 (1982).Google Scholar
15. Hoffman, K.C., Wische, W.E., Wiswall, R.H., Reilly, J.J., Sheehan, T.V., and Waide, C.H., SAE paper 690232 presented at the International Automotive Engineering Conference, Detroit, USA (1969).Google Scholar
16. Lynch, F.E., and Snape, E., Alternative Energy Sources, Vol. 3, p 1479. Veziorglu T.N. Ed., Hemisphere Publishing, Washington D.C. (1978).Google Scholar
17. Strickland, G., Alternative Energy Sources, Vol. 8, p 3699. Veziorglu T.N. Ed., Hemisphere Publishing, Washington D.C. (1978).Google Scholar
18. See for example; the DOE web site: www.eere.energy.gov/hydrogenandfuelcells/ Google Scholar
19. Ovshinsky, S.R., Fetcenko, M.A., Ross, J., Science 260, 176 (1993).Google Scholar
20. Chao, B.S., Young, R.C., Ovshinsky, S.R., Pawlik, D.A., Huang, B., Im, J.S. and Chakoumakos, B.C., Mat. Res. Soc. Symp. Proc. Vol. 575, 193 (2000).Google Scholar
21. Young, R.C., Huang, B., Chao, B.S., and Ovshinsky, S.R., Mat. Res. Soc. Symp. Proc. Vol. 575, 187 (2000).Google Scholar
22. Young, R.C., Chao, B.S., Li, Y., Myasnikov, V., Huang, B., and Ovshinsky, S.R., submitted to 2004 SAE conference.Google Scholar
23. Geiss, R., Webster, B., Ovshinsky, S.R., Stempel, R., Young, R.C., Li, Y., Myasnikov, V., Falls, B., and Lutz, A., submitted to 2004 SAE conference.Google Scholar