Glycerol steam conversion on nano-nickel containing composite materials

The reaction of glycerol steam reforming on new composite materials as a catalysts, resulting from low-temperature wave transformation of the energy component and the Ni-containing particles was studied. We found that for μ-64,8 % Ni/C and μ-41 % Ni/C samples at moderate temperatures (520 °C) values of the glycerol conversion is comparable or even greater than for traditional 65 % Ni/SiO2–Al2O3-catalyst, and the composition of the resulting synthesis gas satisfies the requirements for methanol synthesis. With almost complete conversion of glycerol (t > 700 °C) there is a high selectivity to hydrogen (60 %), which may determine the application of new materials as catalysts for hydrogen production. There is possibility of glycerol with 80 % of water recycling to synthesis gas and hydrogen.

1. Zhang Y., Dube M., McLean D., Kates M. // Bioresource Technology, 2003. Vol. 90. № 3. P. 229.

2. Sutton D., Kelleher B., Ross J. // Fuel Processing Technology, 2001. Vol. 73. № 3. P. 155.

3. Steynberg A.P., Nel H.G. // Fuel, 2004. Vol. 83. P. 765.

4. Zhang B., Tang X., Li Y., Xu Y., Shen W. // Int. J. Hydrogen Energy 2007. Vol. 32. № 13. P. 2367.

5. Zhang B.,. Tang X, Li Y. et al // Catal. Commun. 2006. Vol. 7. P. 367.

6. Czernik S., French R., Feik C., Chornet E. // Ind. Eng. Chem. Res. 2002. Vol. 41. P. 4209.

7. Adhikari S., Fernando S., Haryanto A. // Catalysis Today. 2007. Vol. 129. P. 355.

8. Михайлов Ю.М., Леонова В.Н. Низкотемпературные волновые режимы горения энергетических систем, разбавленных инертными наполнителями и их использование для получения полимерных композитов // ДАН. 2002. Т. 386, № 1. С. 61.

9. Aleshin V., Leonova V., Mikhailov Yu. at al. Cooperative formation of high-porosity polymer matrix and its implantation with nano-particles of transition metals in a low-temperature combustion wave // Proc. of European Polymer Congress. Moscow. 2005. Р. 3.2–2.

10. Matsumura Y., Nakamori T. // Applied Catalysis A: General. 2004. Vol. 258. № 1 P. 107.

11. Hiroki Hayashi, Seiichiro Murata, Teruoki Tago at al. // Chemistry Letters, 2001. Vol. 30. №1. P. 34.