Wave structure and flow amplitude-frequency characteristics in the turbine nozzle lattice in the presence of phase transition-Reference-Cited by-同舟云学术

Wave structure and flow amplitude-frequency characteristics in the turbine nozzle lattice in the presence of phase transition

Published:2017-04-28 Issue:5 Volume:64 Page:379-386
ISSN:0040-6015
Container-title:Thermal Engineering
language:en
Short-container-title:Therm. Eng.

Author:

Gribin V. G.,Gavrilov I. Yu.,Tishchenko A. A.,Tishchenko V. A.,Alekseev R. A.

Publisher

Pleiades Publishing Ltd

Subject

Energy Engineering and Power Technology,Nuclear Energy and Engineering

Link

http://link.springer.com/content/pdf/10.1134/S004060151703003X.pdf

Reference12 articles.

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2. F. Bakhtar and K. Zidi, “Nucleation phenomena in flowing high-pressure steam: Experimental results,” Proc. Inst. Mech. Eng., Part A 203, 195–200 (1989).

3. M. J. Moore, P. T. Walters, R. I. Crane, and B. J. Davidson, “Predicting the fog-drop size in wetsteam turbines,” in Proc. 4th Conf. on Wet Steam, Coventry, UK, Apr. 3–5, 1973 (Mech. Eng. Publ. Inst. Mech. Eng., London, 1973).

4. C. A. Moses and G. D. Stein, “On the growth of steam droplets formed in a laval nozzle using both static pressure and light scattering measurements,” Trans. ASME, Ser. I: J. Fluids Eng. 100, 311–322 (1978).

5. S. Shigeki and J. Alexander, “White non-equilibrium unsteady wet-steam condensation modeling: computations for a steam turbine cascade and a nozzle,” in Proc. Baumann Centenary Conf., Cambridge, Sept. 10–11, 2012 (Univ. of Cambridge, Cambridge, 2012), paper No. BCC-2012-07.