Improving fire protection of ammunition and explosives storage areas

 

Serhii Vazhynskyi

National University of Civil Defenсe of Ukraine

http://orcid.org/0000-0002-1671-3684

 

Igor Fedyuk

National University of Civil Defenсe of Ukraine

http://orcid.org/0000-0001-8374-2108

 

Andrii Chernukha

National University of Civil Defenсe of Ukraine

http://orcid.org/0000-0003-3604-1149

 

DOI: https://doi.org/10.52363/2524-0226-2021-33-22

 

Keywords: ammunition, arsenal, fire extinguishing agent, powder pressure accumulator

 

Abstract

The main parameters of the fire extinguishing system of arsenals, ammunition and explosives storage warehouses and ways of its improvement are determined. The latter made it possible to calculate the number and list of elements of modernization of the fire extinguishing system. A functional model of a modernized automatic fire extinguishing system in warehouses and arsenals is proposed, which should include a set of measures to create additional reservoirs, engineering equipment for explosive substances storage facilities and technical devices for automatic fire extinguishing with high costs of extinguishing agent. The peculiarities of the work are the description of the created experimental installation on the test of which the efficiency of the offered functional model of the modernized automatic fire extinguishing system was confirmed in laboratory conditions. Analysis of preliminary results of calculations and tests confirm that fire protection of explosives in places of their permanent or temporary storage, maintenance and preparation for transportation must be improved by upgrading the system as a whole. Namely, the creation of additional land fortifications, fire reservoirs on the territory, the use of modernized automated fire extinguishing systems in which to use powder pressure accumulators. At the stage of fire, the automatic fire extinguishing system must provide an increase in water consumption by 30%. Proposals are made to create conditions for fire fighting in warehouses and arsenals during works related to storage or utilization of explosive products and substances, the term of storage and use of which has expired by creating and using reserve fire reservoirs in the dangerous area. The directions of improvement of the fire alarm system are determined and the use of the automatic fire extinguishing system, which is energy - independent, noise-resistant, and easy to operate, is proposed.

 

References

  1. On approval of the passport of the budget program «Utilization of ammunition, liquid components of rocket fuel, weapons, military equipment and other military property, survivability and explosion fire safety of arsenal's, bases and warehouses of the Armed Forces of Ukraine» (2020). Order of the Ministry of Defense of Ukraine from № 66, 230–243. Retrieved from https://www.mil.gov.ua/66_hm.pdf
  2. Sherkar, P., Whittaker, A. S., Aref, A. J. (2010). Modeling the effects of detonations of high explosives to inform blast-resistant design // Technical Report MCEER-10–0009. Retrieved from http://mceer.buffalo.edu/pdf/report/10-0009.pdf
  3. Djakovic, Damir and CviklBalić, Katarina (2016). Explosive Remnants of War Contamination Response in Libya // Journal of Conventional Weapons Destruction, 20, 3, 9. Retrieved from https://commons.lib.jmu.edu/cisr-journal/vol20/iss3/9/
  4. Beran, Laurensand Billings, Stephen (2018). Advanced Geophysical Classification of WWII-era Unexploded Bombs Using Borehole Electromagnetics // Journal of Conventional Weapons Destruction, 22, 1, 3. Retrieved from https://commons.lib.jmu.edu/cisr-journal/vol22/iss1/3
  5. Computer Based Decision Support Tools for Helicopter mission Planing in Disaster Relief and Military Operatons. NATO Research and Technology Organization/ 2019 Technical Report No TR-SAS-045. Retrieved from https://www.sto.nato.int/publications/$$TR-SAS-045-ALL
  6. Effective system of early warning and response to emergencies and natural situations / 2018. Retrieved from http://old.ac-rada.gov.ua/img/files/ EUROSAI/Presentation_Yatsiuk_ukr.pdf
  7. Keeley, Robert (2017). Quality Management and Standards for Humanitarian Improvised Explosive Device (HIED) Response Activities // Journal of Conventional Weapons Destruction, 21, 3, 4. Retrieved from https://commons.lib.jmu.edu/cisr-journal/vol21/iss3/4
  8. Pearson, Harold S. (2016). Small Caliber De-Armers: An Answer to Explosive Acquisition Problems // Journal of Conventional Weapons Destruction, 20, 1, 15. Retrieved from https://commons.lib.jmu.edu/cisrjournal/vol20/iss1/15
  9. Geneva International Centre for Humanitarian Demining (GICHD). Retrieved from: https://www.gichd.org
  10. New Technique for the Destruction of Landmines and UXO by Deflagration // Journal of Conventional Weapons Destruction, 22, 2, 7. Retrieved from: https://commons.lib.jmu.edu/cisr-journal/vol22/iss2/7