Raspodela kapljica vode u ravni za suzbijanje požara koji generišu prskalice u sistemima protivpožarne zaštite

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Objavljeno Feb 15, 2026

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Ștefan Dunǎ
Faculty of Civil Engineering, “Politehnica” University of Timisoara, Romania
Lucian Mihoc
Timiș County Emergency Inspectorate, Romania
Ioan Silviu Dobosi
Faculty of Architecture, “Politehnica” University of Timisoara, Romania
Andrei Dunǎ
Faculty of Civil Engineering, “Politehnica” University of Timisoara, Romania

Apstrakt

Ovaj rad proučava raspodelu kapljica vode generisanih protivpožarnim sprinkler sistemima u ravni gašenja. Eksperimentalni rezultati poređeni su sa analitičkim modelima radijalnog opadanja sa ciljem optimizacije efikasnosti gašenja.

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Kako citirati
DUNǍ, Ștefan et al. Raspodela kapljica vode u ravni za suzbijanje požara koji generišu prskalice u sistemima protivpožarne zaštite. Zbornik Međunarodnog kongresa i izložbe o KGH, [S.l.], v. 56, n. 1, p. 105-120, feb. 2026. Dostupno na: <https://izdanja.smeits.rs/index.php/kghk/article/view/8280>. Datum pristupa: 12 mar. 2026
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Broj časopisa
God. 56 Br. 1 (2026): Zbornik radova pisanih za 56. Međunarodni kongres i izložbu o KGH
Sekcija
Moderni sistemi KGH – modeliranje i simulacija
Creative Commons License

Ovaj rad je pod Creative Commons Aуторство-Nekomercijalno-Bez prerade 4.0 Internacionalna licenca.

Reference

[1] *** NFPA 13, Standard for the Installation of Sprinkler Systems, National Fire Protection As-sociation, 2022 Edition.
[2] *** ISO 6182-1, Fire Protection — Automatic Sprinkler Systems — Part 1: Requirements and Test Methods for Sprinklers, 2014.
[3] Buchanan, A. H., Structural Design for Fire Safety, John Wiley & Sons, 2017.
[4] Klote, J. H., and Milke, J. A., Principles of Smoke Management, ASHRAE, 2002.
[5] Rasbash, D.J., Drysdale D., et al., Evaluation of Fire Models, Journal of Fire Sciences, Vol. 25, 2008.
[6] Fleischmann, C. M., Heat Release Rates of Burning Items, Fire Safety Science, Proceedings of the Sixth Symposium, 2000.
[7] Heskestad, G., Sprinkler Technology Research, Fire Suppression Science and Technology Symposium, 1993.
[8] Merci, B. and T. Beji, Fluid Mechanics Aspects of Fire and Smoke Dynamics, CRC Press, 2015.
[9] Chow, W.K., Droplet Behavior in Sprinkler Sprays, Building and Environment Journal, 36(2): 207-214, 2001.
[10] McGrattan, K. et al., Fire Dynamics Simulator Technical Reference Guide (FDS), NIST Special Publication, 2019.
[11] Lucian Vasile Mihoc, Andrei Duna, Ștefan Duna et al. Contributions to the resolution of is-sues relating to the performance of fire extinguishing sprinkler systems. Opatina Croatia The 49th International Symposium ATA 2025
[12] Cosmina Florica, Andrei Dună, Ștefan Dună. et al., Evaluation of the performance of sprin-kler fire extinguishing systems in cold storage using the distribution uniformity coefficient (DU) Kopaonik, Serbia ACCHE 07.02.2025