The analysis of pressure drop, spray angle, and sprinkling intensity distribution in the spray stream produced by the water-foam nozzle-Reference-Cited by-同舟云学术

The analysis of pressure drop, spray angle, and sprinkling intensity distribution in the spray stream produced by the water-foam nozzle

Published:2022-06-01 Issue:2 Volume:24 Page:42-49
ISSN:1899-4741
Container-title:Polish Journal of Chemical Technology
language:en
Short-container-title:

Author:

Ochowiak Marek¹,Krupińska Andżelika¹,Włodarczak Sylwia¹,Matuszak Magdalena¹,Zielińska Patrycja¹,Czernek Krystian²,Witczak Stanisław²,Wilk Tomasz³

Affiliation:

1. Poznan University of Technology , Department of Chemical Engineering and Equipment , Poznan , Poland

2. Opole University of Technology , Faculty of Mechanical Engineering, Department of Process and Environmental Engineering , ul. Pruszkowska 76 , Opole , Poland

3. Adam Mickiewicz University , Faculty of Chemistry , 61-614 Poznan , Poland

Abstract

Abstract This paper summarises a series of large-scale fire suppression tests conducted to simulate a fire in the big surface and/or surface sprinkling. The subject of this paper is the research on water spraying with the use of the Turbo Jet 2011 water-foam nozzle manufactured by Supon Białystok. The results discuss the pressure losses caused by the flow through the discharge hose, spray angle, and the intensity of surface sprinkling. The greatest stream ranges and the highest maximum values of the sprinkling intensity were obtained at the capacity of 400 l/min, and a solid spray angle. The smallest values were obtained at 200 l/min, a pressure of 5 bar, and a solid spray angle. The actual pressures taking into account the losses in the hose section were calculated. As for the highest firefighting effectiveness of the stream, the authors recommended the following parameters: semi spray angle, 200 l/min, and 2.5 bar.

Publisher

Walter de Gruyter GmbH

Subject

General Chemical Engineering,General Chemistry,Biotechnology

Link

https://www.sciendo.com/pdf/10.2478/pjct-2022-0013

Reference25 articles.

1. 1. Gai, G., Hadjadj, A., Kudriakov, S., Mimouni, S. & Tho-mine, O. (2021). Numerical study of spray-induced turbulence using industrial fire-mitigation nozzles. Energies 14(1135). DOI: 10.3390/en14041135.

2. 2. Huang, D.M., Li, L.M., Zhang, H., Xu, C.M., Li, Y. & Yang, H. (2009). Recent progresses in research of fire protection on historic buildings. J. Appl. Fire Sci. 19(1), 63–81. DOI:10.2190/AF.19.1.D.

3. 3. Outinen, J., Samec, J. & Sokol, Z. (2012). Research on fire protection methods and a case study “Futurum”. Proc. Eng. 40, 339–344. DOI: 10.1016/j.proeng.2012.07.105.

4. 4. Zhang, D., Li, Z., Yi, W. & Wang, F. (2013). Test study of spray characteristics of spiral nozzle in the spray tower. Acta Energiae Solaris Sin. 34, 1969–1972. DOI: 10.1051/conf/202017001009.

5. 5. Arvidson, M. (2014). Large-scale water spray and water mist fire suppression system tests for the protection of ro–ro cargo decks on ships. Fire Techn. 50, 589–610. DOI: 10.1007/s10694-012-0312-7.

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