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雾化与喷雾

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ISSN 打印: 1044-5110

ISSN 在线: 1936-2684

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Indexed in

MULTIPOINT STATISTICAL STRUCTURE OF THE IDEAL SPRAY, PART II: EVALUATING STEADINESS USING THE INTERPARTICLE TIME DISTRIBUTION

卷 5, 册 4&5, 1995, pp. 457-505
DOI: 10.1615/AtomizSpr.v5.i45.60
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摘要

Evaluation of the steadiness of sprays is possible using the interparticle time distribution—an easily measurable function that contains information about the expected occurrence rate of droplets in a spray. Combined with ensemble-averaging of spray realizations, the interparticle time distribution permits unambiguous classification of sprays on the basis of the time dependence of their intensity function—the probability density for droplet occurrence. Three major spray classifications are defined: steady, unsteady/deterministic, and unsteady/tochastic. Each of the two latter categories may be further refined, leading to the classifications sinusoidal, complex periodic, almost periodic, transient, strictly stationary, N-point stationary, weakly stationary, and nonstationary. Analytical expressions for the interparticle time distribution are derived for each major category of spray using the ideal spray assumptions. Using these expressions, methods are developed that permit unambiguous classification by means of time-series phase Doppler data. The classification methods (and the existence of the classifications themselves) are then demonstrated by application to data from a nominally steady kerosene spray flame.

对本文的引用
  1. Hong Moongeun, Fleck Brian A., Nobes David S., Unsteadiness of the internal flow in an effervescent atomizer nozzle, Experiments in Fluids, 55, 12, 2014. Crossref

  2. Heinlein Jens, Fritsching Udo, Droplet clustering in sprays, Experiments in Fluids, 40, 3, 2006. Crossref

  3. Stähle Philipp, Gaukel Volker, Schuchmann Heike P., Investigation on the Applicability of the Effervescent Atomizer in Spray Drying of Foods: Influence of Liquid Viscosity on Nozzle Internal Two-Phase Flow and Spray Characteristics, Journal of Food Process Engineering, 38, 5, 2015. Crossref

  4. Gualtieri Carlo, Chanson Hubert, Interparticle arrival time analysis of bubble distributions in a dropshaft and hydraulic jump, Journal of Hydraulic Research, 51, 3, 2013. Crossref

  5. Heinlein J., Schulte G., Fritsching U., Guardani R., Mapping the structure of a liquid spray by means of neural networks, Chemical Engineering and Processing: Process Intensification, 46, 12, 2007. Crossref

  6. Liu Meng, Duan Yufeng, Zhang Tienan, Xu Yiqian, Evaluation of unsteadiness in effervescent sprays by analysis of droplet arrival statistics – The influence of fluids properties and atomizer internal design, Experimental Thermal and Fluid Science, 35, 1, 2011. Crossref

  7. Liu Meng, Duan YuFeng, Zhang TieNan, Evaluation of effervescent atomizer internal design on the spray unsteadiness using a phase/Doppler particle analyzer, Experimental Thermal and Fluid Science, 34, 6, 2010. Crossref

  8. Hájek Jiří, Dohnal Miloslav, Vondál Jiří, Broukal Jakub, Analysis of effervescent spray quality for oil-fired furnace application, Clean Technologies and Environmental Policy, 17, 5, 2015. Crossref

  9. Sun Chunhua, Ning Zhi, Lv Ming, Yan Kai, Fu Juan, Time–frequency analysis of acoustic and unsteadiness evaluation in effervescent sprays, Chemical Engineering Science, 127, 2015. Crossref

  10. Widmann John, Presser Cary, Leigh Stefan, Effect of burst-splitting events on phase Doppler interferometry measurements, 39th Aerospace Sciences Meeting and Exhibit, 2001. Crossref

  11. Sun Chunhua, Ning Zhi, Lv Ming, Yan Kai, Fu Juan, Acoustic performance of effervescent sprays by time–frequency method with different atomizer structures under different operating conditions, International Journal of Multiphase Flow, 82, 2016. Crossref

  12. Li Xing-gang, Fritsching Udo, Spray Transport Fundamentals, in Metal Sprays and Spray Deposition, 2017. Crossref

  13. Acharya Akshay S., Deevi Srivallabha, Dhivyaraja K., Tangirala Arun K., Panchagnula Mahesh V., Spatio-temporal microstructure of sprays: data science-based analysis and modelling, Journal of Fluid Mechanics, 912, 2021. Crossref

  14. Shin Dongyun, Rodrigues Neil S., Bokhart Andrew J., Sojka Paul E., Gore Jay P., Lucht Robert P., Spray Characteristics of Standard and Alternative Aviation Fuels at Cold-start Conditions, AIAA Journal, 59, 12, 2021. Crossref

  15. Li Genbao, Li Chuqiao, Experimental study on the spray steadiness of an internal-mixing twin-fluid atomizer, Energy, 226, 2021. Crossref

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