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A Study on the Characteristics of an Optical Sensor Linear Fire Detection System with Miniature Model Fire Experiment
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  • Journal title : Fire Science and Engineering
  • Volume 30, Issue 2,  2016, pp.19-26
  • Publisher : Korea Institute of Fire Science and Engineering
  • DOI : 10.7731/KIFSE.2016.30.2.019
 Title & Authors
A Study on the Characteristics of an Optical Sensor Linear Fire Detection System with Miniature Model Fire Experiment
Kim, Dong-Eun; Kim, Si-Kuk; Lee, Young-Sin; Lee, Chun-Ha; Lim, Woo-Sup;
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In this study, we conducted a low temperature operating test and miniature tunnel model test to study the fire detection capability and properties of an early fire detection system using an optical sensor linear detector that can be installed in harsh environments such as tunnel or utility-pipe conduits which are becoming the major and national infrastructure facilities. The test showed that the optical sensor linear detector was the only one functioned properly among five thermal detectors installed at a low temperature of for 5 days. To study were analyzed adaptability of optical sensor linear detector in the windy tunnel, the operating properties of the optical sensor linear detector when the wind velocity was varied between 0 m/s and 1 m/s in a miniature tunnel model. The temperature change was high when the wind velocity was 0 m/s.
Optical sensor linear fire detection system;Miniature model fire experiment;
 Cited by
Ministry of Public Safety and Security, "Fire safety standards for road tunnel (NFSC 603)" (2015).

EN 52-22, "Fire detection and fire alarm system-Part 22: Resettable line-type heat detectors", pp. 9-13 (2014).

UL 521, "Heat detectors for fire protective signaling systems", Part. 5, pp. 50-51 (1993).

ISO 7240-5:2014, "Fire detection and alarm systems-Part 5: Point-type heat detectors (2012).

AS 4825-2011, "Australian Standard Tunnel fire safety" (2011).

NFPA 502, "Standard for Road Tunnels, Bridges, and Other Limited Access Highways" (2011).

H. Tsuneo, S. Kaoru, T. Mitsuhiro and K. Yahei, "Development of a Distributed Sensing Technique Using Brillouin Scattering", Journal of Lightwave Technology, Vol. 13, No. 7, pp. 1296-1302 (1995). crossref(new window)

Y. Sakairi, H. Uchiyama, Z. X. Li and S. Adach, "System for Measuring Temperature and Strain Separately by BOTDR and OTDR", Proc. SPIE 4920, pp. 274-284 (2002).

J. Park, G. Bolognini, D. Lee, P. Kim, P. Cho, F. Di Pasquale and N. Park, "Raman-based Distributed Temperature Sensor with Simplex Coding and Link Optimization", IEEE Photonics Technology Letters, Vol. 18, No. 17, pp. 1879-1881 (2006). crossref(new window)

C. E. Lee and H. F. Taylor, "Fiber-optic Fabry-perot Temperature Sensor Using a Low-coherence Light Source", J. Lightw. Technol., Vol. 9, No. 1, pp. 129-134 (1991). crossref(new window)

Siemens, "Optical Sensor Linear Detector System Operation Manual (Korean)", pp. 11-12 (2010).

LIOS Technology, "Linear Heat Detection Systems for Fire Detection Controllers OTS1000(-LR) to OTS4000 (-LR) Catalog", pp. 2-3 (2010).

Bandweaver, "Fire Laser Linear Heat Detection Data Sheet", pp. 1-2 (2015).

AP Sensing, "Fiber Optic Linear Heat Detection Controller Catalog" (2015).

Y. K. Kang, S. R. Ahn, S. A. Lee and S. S. An, "A Study on the Analysis of Cuttent Installation Status for Underground Common Utility Tunnel", Proceedings of Koren Socitey of Civil Engineers Conference, Vol. 2007, No. 10, pp. 3011-3014 (2007).

D. E. Kim, Y. C. Shin and Y. J. Kwon, "A Investigation Study on the Maintenance Management for Fire Safety According to Analysis of Fire Accident in Korea", Proceedings of the Korea Institute of Fire Science and Engineering Conference, Vol. 2008, No. 1, pp. 328-333 (2008).

KOFEIS 0301, Standards of Model Approval and Inspection Technology for Fire Detectors, pp. 18-33 (2015).