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Systematization andgeneralization of local exhaust devices characteristics - the basis forengineering design techniques of effective industrial ventilation

doi: 10.5862/MCE.32.8

Systematization and generalization of local exhaust devices characteristics - the basis for engineering design techniques of effective industrial ventilation

A.G. Sotnikov, NP «AVOK - Northwest», Saint-Petersburg, Russia
A.A. Borovitskiy, Vladimir State University, Vladimir, Russia

The modern development of the industry, new technologies and a lot of harmful substances more than 2500 names attracts a lot of attention to industrial ventilation systems. The subject of this paper is analysis and generalization of foreign experience within the limits of proposed theory. In this paper, as a continuation of the previous papers the basics of designing effective industrial ventilation systems by optimizing air flow were described.

An integrated exponential power dependence for defining the recovery effectiveness of different harmful substances by different local exhaust devices was proposed. The conception of equivalent effective velocity was proposed and substantiated.

The method of optimal air exchange calculation and engineering design techniques were proposed.

Key words:

ventilation; hazard; concentration; local exhaust device; efficiency; recovery coefficient; optimization; equivalent effective velocity

Read the whole article (rus) in pdf

(Sotnikov A.G., Borovitskiy A.A. Systematization and generalization of local exhaust devices characteristics - the basis for engineering design techniques of effective industrial ventilation // Magazine of Civil Engineering. 2012. №6 (32). Pp. 54-59).


References:

  1. Sotnikov A. G., Borovitskiy A. A. Magazine of Civil Engineering. 2012. No. 2 (28). Pp. 32-38. (rus)

  2. Sotnikov A. G., Borovitskiy A. A. Mir stroitelstva i nedvizhimosti [World of Construction and Real Estate]. 2012. No. 44. (rus)

  3. Borovitskiy A. A. Innovatsii v stroitelstve i arkhitekture [Innovation in construction and architecture]. 2012. Pp. 80-88. (rus)

  4. Kamenev P. N., Tertichnik E. I. Ventilyatsiya: uchebnoe posobie [Ventilation: manual]. Moscow: ASV,2008. 624 p. (rus)

  5. Burgess W. A. Ventilation for control of the work environment. Hoboken: John Wiley & Sons, 2004. 437 p.

  6. Niemela R. Comparison of three tracer gases for determining ventilation effectiveness and capture efficiency. British Occupational Hygiene Society. 1990. Vol. 35. No. 4. Pp. 405-417.

  7. Régnier R. Cuves de traitement de surface. Hygiéne et Sécurité du Travail. 1996. No. 165. Pp. 425-441.

  8. Braconnier R. Efficacité d’une fente d’aspiration sur une cuve de traitement de surface. Hygiéne et Sécurité du Travail. 1991. No. 144. Pp. 463-478.

  9. Cornu J. C. Torches aspirantes de soudage MIG/ MAG. Hygiéne et Sécurité du Travail. 1991. No. 145. Pp. 663-670.

  10. Flynn M. Capture efficiency of flanged circular local exhaust hoods. The Annals of Occupational Hygiene. 1986. No. 30 (4). Pp. 497-513.

  11. Li Y. A Short note on capture efficiency of kitchen range hoods in a confined space. International Journal on Architectural Science. 2001. Vol. 2. No. 2. Pp. 46-52.

  12. Devienne R. Experimental Characterization of a Plume of Passive Contaminant above a Thermal Source: Capture Efficiency of a Fume Extraction Hood. The Annals of Occupational Hygiene. 2009. Vol. 53. No. 7. Pp. 739-748.

  13. Takano S. Capture Efficiency and Indoor Thermal Environment inside Commercial Kitchen using Low Radiation Cooking Equipment with Concentrated Exhaust. AIVC 29th Conference. Kyoto, Japan, October 14-16. 2008. Pp. 1-6.

  14. Takano S. Capture Efficiency of Exhaust Hood for Commercial Kitchen using Low Radiation Cooking Equipment with Concentrated Exhaust. The 9th International Conference on Industrial Ventilation. Zurich, Switzerland, October 18-21. 2009. Pp. 1-6.

  15. Popiolek Z. Improvement of a plume volume flux calculation method. Proceedings of the 6th International Conference on Air Distribution in Rooms. Stockholm, Sweden, June 14-17. 1998. Vol. 1. Pp. 423-430.

  16. Yik F. W. H. Flow rate and capture efficiency of domestic kitchen exhaust hoods for chinese households. International Journal on Architectural Science. 2002. Vol. 3. No. 3. Pp.125-134.

  17. Kosonen R. Analysis of Capture and Containment Efficiency of a Ventilated Ceiling. International Journal of Ventilation. 2003. Vol. 2. No. 1. Pp. 33-43.

  18. Huang R. F. Aerodynamic Characteristics and Design Guidelines of Push–Pull Ventilation Systems. British Occupational Hygiene Society. 2005. Vol. 49. No. 1. Pp. 1-15.

  19. GN 2.2.5.1313-03 Predelno dopustimyye kontsentratsii (PDK) vrednykh veshchestv v vozdukhe rabochey zony [Maximum allowable concentration of harmful substances in the air of the working area]. Moscow, 2003. 200 p. (rus)

  20. Sbornik metodik po raschetu vybrosov v atmosferu zagryaznyayushchikh veshchestv razlichnymi proizvodstvami [Collection methods for the calculation of emissions of air pollutants by various industries]. Leningrad: Gidrometeoizdat, 1986. 183 p. (rus)

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