THERMAL SCIENCE

International Scientific Journal

Darko N. Zigar

,

Milan Đ Blagojević

,

Dušica Pešić

,

Aca V. Božilov

,

Vlastimir D. Nikolić

SMOKE DETECTOR PLACEMENT IN COMPARTMENTS WITH HONEYCOMB CEILING: A NUMERICAL STUDY

ABSTRACT
One of the most interesting problems in fire detection system design is the problem referred to as detector position on a ‘honeycomb ceiling’, because beams and joists affect stratification of smoke and, consequently, smoke detector response time. The aim of this paper is to determine optimal smoke detector placement on the underside of beams or on the structural slab in the cells. On the basis of rules of standards for smoke detector location, the large eddy simulation method of fire dynamics simulator software package was employed to investigate the effects of ‘honeycomb’ density on smoke detector response time. The simulation results show that the columns, beams, joists and similar structural elements affect stratification of smoke and, consequently, smoke detector response time. In the case when the honeycomb cells are small, the detectors on the underside of the beams react faster because the smoke does not enter the cells in sufficient quantity to activate the optical smoke detector located on the structural plate in the cells that form the beams. On the basis of the obtained results, a satisfactory solution for most possible situations that could occur in practice has been proposed.
KEYWORDS
honeycomb ceiling, fire detection, fire dynamics simulator, simulation, smoke detector location
PAPER SUBMITTED: 2022-08-19
PAPER REVISED: 2022-11-21
PAPER ACCEPTED: 2022-11-29
PUBLISHED ONLINE: 2023-01-07
DOI REFERENCE: https://doi.org/10.2298/TSCI220819205Z
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Issue 3, PAGES [2489 - 2500]
REFERENCES
  1. Wang, P., Wu, N., Luo, H., Sun, Z., Study on vibration response of a non-uniform beam with nonlinear boundary condition, Facta Universitatis Series: Mechanical Engineering, 19(4), (2021), pp. 781-804. doi: 10.22190/FUME210324045W.
  2. Safaei, B., Onyibo, E.C., Hurdoganoglu, D., Thermal buckling and bending analyses of carbon foam beams sandwiched by composite faces under axial compression, Facta Universitatis Series: Mechanical Engineering, doi: 10.22190/FUME220404027S.
  3. Sewell, J., High speed cost efficient honeycomb core process technology bringing innovation in building materials and applications, Reinforced plastics, 61(6), (2017), pp. 335-338, doi: 10.1016/j.repl.2017.06.090.
  4. Hu, H., Belouettar, S., Potier-Ferry, M., Makradi, A., A novel finite element for global and local buckling analysis of sandwich beams, Composite Structures, 90(3), (2009), pp. 270-278, doi: 10.1016/j.compstruct.2009.02.002.
  5. Wang, D., Abdalla, M.M., Global and local buckling analysis of grid-stiffened composite panels, Composite Structures, 119, (2015), pp. 767-776, doi: 10.1016/j.compstruct.2014.09.050.
  6. Zhang, Z., Zhou, D., Fang, H., Zhang J., Li, X., Analysis of laminated beams with temperature-dependent material properties subjected to thermal and mechanical loads, Composite Structures 227, 111304, (2019), doi: 10.1016/j.compstruct.2019.111304.
  7. Hu, J.S., Wang, B.L., Crack growth behavior and thermal shock resistance of ceramic sandwich structures with an auxetic honeycomb core, Composite Structures, 260, 113256, (2021), doi: 0.1016/j.compstruct.2020.113256.
  8. Razdolsky, L., Transient engineering creep of materials under various fire conditions. In: Probability Based High Temperature Engineering, Springer, (2017), doi: 10.1007/978-3-319-41909-1_5.
  9. Pešić, D.J., Raos M.T., 2017, Požari i građevinske konstrukcije, Univerzitet u Nišu, Fakultet zaštite na radu u Nišu, 219 str.
  10. Stepinac, L., Galić, J., Vukić, H., Haima, M., Overview of research on fire effects in RC elements and assessment of RC structures after fire, Građevinar, 73(5), (2021), pp. 509-522, doi: 10.14256/JCE.3196.2021.
  11. Fan, K., Li, J., Yu M., Wu M., Yao, Y., Compressive stress-strain relationship for stressed concrete at high temperatures, Fire Safety Journal, 130, 103576, (2022), doi: 10.1016/j.firesaf.2022.103576.
  12. Moghadam, M.A., Izadifard, R., Evaluation of shear strength of plain and steel fibrous concrete at high temperatures, Construction and Building Materials, 215, (2019), pp. 207-216, doi: 10.1016/j.conbuildmat.2019.04.136.
  13. Wang, W., Lu, C., Li, Y., Li, Q., An investigation on thermal conductivity of fly ash concrete after elevated temperature exposure, Construction and Building Materials, 148, (2017), pp. 148-154, doi: 10.1016/j.conbuildmat.2017.05.068.
  14. Durgun, M.Y., Sevinç, A.H., High temperature resistance of concretes with GGBFS, waste glass powder, and colemanite ore wastes after different cooling conditions, Construction and Building Materials, 196, (2019), pp. 66-81, doi: 10.1016/j.conbuildmat.2018.11.087.
  15. Blagojevic, M., Projektovanje sistema za dojavu požara, AGM knjiga, (2018), Beograd, 266 str.
  16. Blagojevic, M., Jevtic, R., Ristic, D., Comparative analysis of rules in five leading standards for smoke detectors sitting in the presence of ceiling irregularity, Transactions of the VSB, 12(2), (2017), pp. 23-29, doi: 10.1515/tvsbses-2017-0011.
  17. EN 54-14:2018 Fire detection and fire alarm system - Part 14: Guidelines for planning, design, installation, commissioning, use and maintenance, European Committee for Standardization (CEN), Brussels, Belgium.
  18. DIN VDE 0833-2:2017 Alarm systems for fire, intrusion and hold up - Part 2: Requirements for fire alarm systems, VDE Verlag, Berlin, Germany.
  19. BS 5839-1:2017 Fire detection and fire alarm systems for buildings. Code of practice for design, installation, commissioning and maintenance of systems in non-domestic premises, British Standards Institution, London, United Kingdom.
  20. NFPA 72:2022 National Fire Alarm and Signaling Code, National Fire Protection Association, Quincy, Massachusetts, U.S.
  21. СП 484.1311500:2020 Системы противопожарной защиты. Системы пожарной сигнализации и автоматизация систем противопожарной защиты. Нормы и правила проектирования, ВНИИПО МЧС, Москва, Россия.
  22. McGrattan, K., McDermott, R., Weinschenk, C., Forney, G., 2013, Fire Dynamics Simulator, Technical Reference Guide, Special Publication (NIST SP), National Institute of Standards and Technology, Gaithersburg, MD, doi:10.6028/NIST.sp.1018.
  23. UL 268:2016 UL Standard for Safety Smoke Detectors for Fire Alarm Systems, American National Standards Institute, Washington, U.S.
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Smoke detector placement in compartments with honeycomb ceiling: A numerical study

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence