The Study of Heat Transfer and Mass Transfer for the Large Capacity Mg-3Ni-2MnO2 Hydrogen Storage Material

Wen Cong Zhang; X.L. Wang; Erde Wang

doi:10.4028/www.scientific.net/MSF.488-489.881

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The Study of Heat Transfer and Mass Transfer for the Large Capacity Mg-3Ni-2MnO₂ Hydrogen Storage Material
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The Study of Heat Transfer and Mass Transfer for the Large Capacity Mg-3Ni-2MnO₂ Hydrogen Storage Material

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Periodical:

Materials Science Forum (Volumes 488-489)

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881-884

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.488-489.881

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Online since:

July 2005

Authors:

Wen Cong Zhang, X.L. Wang, Erde Wang

Keywords:

Ball Milling, Heat Transfer, Mass Transfer, Mg-Based Hydrogen Storage Material

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References

[1] N. Spassov, U. Koester: Journal of Alloys and Compounds Vol. 287 (1999), P.243

Google Scholar

[2] W. Oelerich,T. Klassen and R. Bormann: Journal of Alloys and Compounds Vol.315 (2001), P.237

Google Scholar

[3] Zhenxing Yu, Zuyan Liu, Wang Erde: Journal of Alloys and Compounds Vol. 333 (2002), P.207

Google Scholar

[4] Muthukumar, P. Prakash Maiya, M. Murthy, S. Srinivasa: International Journal of Hydrogen Energy Vol. 27 (2002), P.1083

Google Scholar

[5] Chen Yun, Sequeira, Cesar A.C., Chen Changpin, Wang Xinhua, Wang Qidong: International Journal of Hydrogen Energy Vol. 28 (2002), P.329

Google Scholar

[6] Guo Zhixiong, Sung Hyung Jin：International Journal of Heat and Mass Transfer Vol. 42 (1999), P.379

Google Scholar

[7] T. Nakagawa, A. Inomata, H. Aoki, T. Miura: International Journal of Hydrogen Energy, Vol. 25 (2000), P.339

Google Scholar

[8] S.Ben Nasrallah, A.Jemni: International Journal of Hydrogen Energy Vol. 22 (1997), P.67

Google Scholar

[9] Kemal Aldas, Mahmut D. Mat, Yuksel Kaplan: International Journal of Hydrogen Energy Vol.27 (2002), P.1049

Google Scholar

[10] Wang Er-de, Zhang Wen-cong, Yu Zheng-xing: Trans. Nonferrous Met. Soc. China Vol.13 (2003), P.50 0 500 1000 1500 2000 2500 3000 290 300 310 320 330 340 1:r=0mm 2:r=6.25mm 3:r=12.5mm 3 2 1 Temperature, oC Desorption time, s 0 500 1000 1500 2000 2500 290 300 310 320 330 340 350 360 1:r=0mm 2:r=6.25mm 3:r=12.5mm 3 2 1 Temperture, oC Desorption time, s Fig.8 The temperature field evolution curves of Mg-3Ni-2MnO2 reaction bed during dehydriding process at the temperature (a)320� and (b)340� under 0.1 MPa pressure

Google Scholar