Search in:

Advanced search

Particulate Science and Technology

An International Journal

Volume 32, 2014 - Issue 6

Submit an article Journal homepage

107

Views

CrossRef citations to date

Altmetric

Original Articles

Investigation of the Growth of Particles Produced in a Laval Nozzle

Ehsan Zhalehrajabi Chemical Engineering Department, Universiti Teknologi PETRONAS, Tronoh, Perak, Malaysia

Nejat Rahmanian School of Engineering and Informatics, University of Bradford, Bradford, UKCorrespondence[email protected]; [email protected]

Saeed Zarrinpashne Gas Research Division, Research Institute of Petroleum Industry, Tehran, Iran

Periyasamy Balasubramanian Chemical Engineering Department, Universiti Teknologi PETRONAS, Tronoh, Perak, Malaysia

Pages 595-601 | Published online: 30 Oct 2014

Cite this article
https://doi.org/10.1080/02726351.2014.933459
CrossMark

Full Article
Figures & data
References
Citations
Metrics
Reprints & Permissions

References

Abramowitz , M. , and I. A. Stegun . 1972 . Handbook of mathematical functions with formulas, graphs, and mathematical tables [ 9th printing ] New York : Dover .
Google Scholar
Bayazitoglu , Y. , F. R. Brotzen , and Y. Zhang , Y. 1996 . Metal vapour condensation in a converging nozzle . NanoStrucured Materials 7 : 789 – 803 .
Web of Science ®Google Scholar
Binnie , A. M. , and J. R. Green . 1942 . An electrical detector of condensation in high-velocity steam . Proceeding of the Royal Society London A 181 : 134 – 154 .
Google Scholar
Brooks , G. A. , S. Trang , P. J. Witt , M. N. Hasan , and M. Nagle . 2006 . The carbothermic route to magnesium . Journal of Materials Science and Engineering 58 ( 5 ): 51 – 55 .
Google Scholar
Hasan , M. N. , G. A. Brooks , P. Witt , and T. Barton . 2006 . Design of supersonic nozzles for ultra-rapid quenching of metallic vapours . Proceedings of Materials Processing Fundamentals , TMS 2006, Warrendale PA : TMS .
Google Scholar
Heath , C. H. , K. Streletzky , and B. E. Wyslouzil . 2002 . H2O-D2O condensation in a supersonic nozzle . Journal of Chemical Physics 13 ( 117 ): 6176 – 6185 .
Google Scholar
Hill , P. G. 1966 . Condensation of water vapour during supersonic expansion in nozzles . Journal of Fluid Mechanics 25 ( 3 ): 593 – 620 .
Web of Science ®Google Scholar
Hill , P. G. , H. Witting , and E. P. Demetri . 1963 . Condensation of metal vapors during rapid expansion . Journal of Heat Transfer 85 ( 4 ): 303 – 314 .
Google Scholar
Khan , A. , C. H. Heath , and U. M. Dieregsweiler . 2003 . Homogeneous nucleation rates for D2O in a supersonic Laval nozzle . Journal of Chemical Physics 119 ( 6 ): 3138 – 3174 .
Web of Science ®Google Scholar
Koo , A. , G. A. Brooks , and M. Nagle . 2008 . Nucleation and growth of Mg condensate during supersonic gas quenching . Journal of Crystal Growth 310 ( 10 ): 2659 – 2667 .
Web of Science ®Google Scholar
Kremmer , M. , and O. Okurounmu . 1965 . Condensation of ammonia vapor during rapid expansion. Gas Turbine Laboratory, Massachusetts Institute of Technology : Cambridge , MA .
Google Scholar
Kuan , B. T. , and P. J. Witt . 2013 . Modeling supersonic quenching of magnesium vapour in a Laval nozzle . Chemical Engineering Science 87 : 23 – 39 . doi: http://dx.doi.org/10.1016/j.ces.2012.09.021
Web of Science ®Google Scholar
Moses , C. A. , and G. D. Stein . 1978 . On the growth of steam droplets formed in a Laval nozzle using both static pressure and light scattering measurements . Journal of Fluids Engineering 100 ( 3 ): 311 – 322 . doi: 10.1115/1.3448672
Web of Science ®Google Scholar
Oosthuizen , P. H. , and W. E. Carscallen . 1997 . Compressible fluid flow . New York : McGraw-Hill .
Google Scholar
Oswatitsch , K. 1942 . Kondensationserscheinungen in Überschalldüsen . Journal of Applied Mathematics and Mechanics 22 : 1 – 13 . doi: 10.1002/zamm.19420220102
Google Scholar
Sidin , R. S. R. 2009 . Droplet size distribution in condensing flow . Doctoral desertation, University of Twente, Enschede : the Netherlands
Google Scholar
Sinha , S. , B. E. Wyslouzil , and G. Wilemski . 2009 . Modeling of H2O/D2O condensation in supersonic nozzles . Aerosol Science and Technology 43 ( 1 ): 9 – 24 .
Web of Science ®Google Scholar
Smith , J. M. , H. C. V. Ness , and M. M. Abbott . 2005 . Introduction to chemical engineering thermodynamics, , 7th ed. New York : McGraw Hill Higher Education
Google Scholar
Sung , J. C. , and J. Lin . 2010 . Diamond nanotechnology, , 1st ed . Pan Stanford Publishers.
Google Scholar
Vargaftik , N. B. , B. N. Volkov , and L. D. Voljak . 1983 . International tables of the surface tension of water . Journal of Physical Chemical 12 ( 3 ): 817 – 820 .
Web of Science ®Google Scholar
Wegener , P. P. , and A. A. Pouring . 1964 . Experiments on condensation of water vapor by homogeneous nucleation in nozzles . Physics of Fluids 7 : 352 .
Web of Science ®Google Scholar
Wyslouzil , B. , C. Heath , and L. Cheung . 2000 . Binary condensation in a supersonic nozzle . Journal of Chemical Physics 17 ( 113 ): 7317 – 7329 .
Google Scholar
Yang , Y. , and S. Shen . 2009 . Numerical simulation on non-equilibrium spontaneous condensation in supersonic steam flow . International Communications in Heat and Mass Transfer 36 : 902 – 907 .
Web of Science ®Google Scholar
Yang , Y. , S. Shen , T. Kong , and K. Zhang . 2010 . Numerical investigation of homogeneous nucleation and shock effect in high-speed transonic steam flow . Heat Transfer Engineering 12 ( 31 ): 1007 – 1014 .
Google Scholar
Zhalehrajabi , E. , N. Rahmanian , and N. Hasan . 2013 . Effects of mesh grid and turbulence models on heat transfer coefficient in a convergent–divergent nozzle . Asia‐Pacific Journal of Chemical Engineering 9 ( 2 ): 265 – 271 .
Web of Science ®Google Scholar

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.

People also read
Recommended articles
Cited by

To cite this article:

Reference style: APA Chicago Harvard

Citation copied to clipboard

Reference styles above use APA (6th edition), Chicago (16th edition) & Harvard (10th edition)

Download citation

Download a citation file in RIS format that can be imported by citation management software including EndNote, ProCite, RefWorks and Reference Manager.

Choose format: RIS BibTex RefWorks Direct Export

Choose options: Citation Citation & abstract Citation & references

Investigation of the Growth of Particles Produced in a Laval Nozzle

References

Information for

Open access

Opportunities

Help and information

Your download is now in progress and you may close this window

Login or register to access this feature

Investigation of the Growth of Particles Produced in a Laval Nozzle

References

Reprints and Corporate Permissions

Academic Permissions

Related research

To cite this article:

Download citation

Information for

Open access

Opportunities

Help and information

Keep up to date